JP2011193163A - Mobile communication terminal and communication quality display method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform CQI measurement even in standby to suitably display communication quality. <P>SOLUTION: This mobile communication terminal detects receiving quality of a radio signal from a base station, generates channel state information including an MCS level of an MCS based on the receiving quality to be detected by processing in a receiving quality detection step among a plurality of MCSs for each resource block included in a frequency band which the base station utilizes, calculates an estimated MCS level when data communication is performed with the base station based on the channel state information for each resource block to display the estimated MCS level to be calculated. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a mobile communication terminal and a communication quality display method, and more particularly, to a mobile communication terminal and a communication quality display method capable of adaptively controlling a modulation scheme and an error correction coding rate.

  In recent years, the transmission speed of wireless communication in mobile communication terminals has been increased, and with the increase in transmission speed, the data capacity that users use with mobile communication terminals has also increased. Further, after the 3.5th generation (referred to as “3.5G”) communication method such as HSDPA (High Speed Downlink Packet Access), a mobile communication system including a mobile communication terminal as a constituent element is adaptive modulation / demodulation coding ( By adopting the AMC (Adaptive Modulation and Channel Coding) method, the transmission rate is increased and the quality is improved. This AMC (adaptive modulation / demodulation coding) technique is a technique related to adaptive link control that selects an optimal combination of modulation scheme and channel coding rate (error correction coding rate) according to the propagation environment. It is described in. AMC is also known as LTE (Long Term Evolution), a standard for a next-generation mobile communication system that realizes a data rate (transmission speed) exceeding 100 [Mbps] (for example, see Non-Patent Document 2). Adoption has been decided.

  FIG. 1 is a conceptual diagram for explaining an AMC (Adaptive Modulation / Demodulation Coding) system employed in a conventional mobile communication system. Here, when the mobile communication system is an LTE system, PDSCH (Physical Downlink Shared Channel) is commonly used by a plurality of users (user mobile communication terminals) based on allocation by the scheduler. Physical channel used for transmission of user data to be transmitted, multicast data closed to one cell, and higher layer control information. An adaptive link control technique based on AMC is applied to this PDSCH. That is, three modulation schemes of QPSK (Quadrature Phase Shift Keying), 16QAM (Quadrature Amplitude Modulation), and 64QAM can be applied to PDSCH, and the modulation scheme is selected based on CQI (Channel Quality Indicator). When the channel state value is higher than the reference value and the channel state is good, the modulation method is switched to high-speed transmission using 16QAM or 64QAM by AMC, and the channel state value is lower than the reference value. When the state is bad, the modulation scheme is switched to high-reliability transmission using QPSK by AMC. The specific contents of the AMC method will be described below with reference to FIG.

  In the case of FIG. 1, mobile communication terminals 2-1 and 2-2 exist around the base station 1, and the mobile communication terminal 2-1 is located at a distance D1 from the base station 1, and mobile communication Since the terminal 2-2 is located at a distance D2 from the base station 1, and the distance D2 is larger than the distance D1, the mobile communication terminal 2-1 is closer to the base station 1 than the mobile communication terminal 2-2. It shall be located at a point.

  In general, if the transmission power from the base station 1 is constant, the mobile communication terminal 2-1 that is relatively close to the base station 1 is more mobile than the mobile communication terminal 2-2 that is relatively far from the base station 1. A radio signal from the base station 1 can be received with large electric power. Therefore, in the case of the mobile communication terminal 2-1, it is estimated that the value indicating the channel state for the mobile communication terminal 2-1 is higher than the reference value and the channel state (transmission path state) is good. A large value is used for the multi-value number and the channel coding rate (error correction coding rate). For example, 16QAM or 64QAM having low error resistance is used for the modulation scheme, and 3/4 is used for the channel coding rate R, for example. As a result, the transmission method is switched to high-speed transmission. On the other hand, the mobile communication terminal 2-2 can receive a radio signal from the base station 1 with less power than the mobile communication terminal 2-1. Accordingly, since the value indicating the channel state for the mobile communication terminal 2-2 is lower than the reference value and the channel state is estimated to be bad, a small value is adopted for the modulation multi-level number and the coding rate. In addition, QPSK or the like having high error tolerance is used, and for example, 1/3 is used for the channel coding rate R, so that the transmission method is switched to low speed transmission (high reliability transmission). Therefore, if the user can perform data communication in an environment with good transmission efficiency, the communication time associated with data communication can be greatly shortened, and power consumption can be reduced in the mobile communication terminal.

  However, when a mobile communication terminal using a 3.5G mobile communication system that is currently in operation displays a channel state for the mobile communication terminal, generally, the mobile communication terminal is configured to receive RSSI (Received Signal). Only the signal strength of the received signal is displayed using an indicator of about 4 steps using Strength Indicator. FIG. 2 shows a conventional method for displaying the signal strength of a received signal using an indicator of about four steps using RSSI.

  FIG. 3 shows a configuration of a conventional mobile communication terminal 2. In a mobile communication system that employs adaptive modulation / demodulation coding techniques, communication services are generally serviced on a best-effort basis without service quality assurance. Therefore, the conventional mobile communication terminal 2 which is a mobile station selects the base station 1 with the best reception quality, and the SINR (Signal-to-interference-plus-Noise Ratio) of the mobile communication terminal 2 (Noise ratio) The wireless transmission path quality is measured using the measurement unit 25. Then, the CQI (Channel Quality Indicator) information generation unit 26 of the conventional mobile communication terminal 2 determines a receivable transmission format (combination of modulation scheme and channel coding rate) based on the measurement result. Then, the conventional mobile communication terminal 2 controls the transmission signal processing unit 28 and the radio unit 12, and uses the transmission format determined by the CQI information generation unit 26 as channel state information (CQI information: Channel Quality Indicator information). Report to 1. The base station switches the modulation scheme and channel coding scheme (MCS) combination of data to be transmitted to the mobile station based on the report on the channel state information from the mobile station. As a result, the mobile communication system employing the adaptive modulation / decoding coding technique has a high data transmission rate although the error tolerance is low when the reception state at the mobile communication terminal 2 as the mobile station is better than the reference value. On the other hand, when the reception state at the mobile communication terminal 2 is deteriorated from the reference value, it is possible to transmit / receive transmission information through a dedicated information channel using a data transmission rate that is low speed but high in error tolerance. It becomes.

  Typical examples of the value indicating the quality of the wireless transmission path include SIR (Signal to Interference power Ratio) and SINR (Signal to Interference plus Noise power Ratio) of the received signal. When the mobile communication terminal is waiting, the mobile communication terminal does not need to transmit CQI information to the base station 1. For this reason, when the mobile communication terminal is waiting, the mobile communication terminal does not perform normal CQI information generation processing.

  FIG. 4 shows the correspondence between the wireless transmission path quality and the CQI Index. In the case of FIG. 4, the value indicating the radio transmission quality is the SINR of the received signal, and the CQI index is associated with each SINR [dB] range (CQI range). Specifically, CQI index1 is associated with a range in which SINR [dB] is 5.0 to 6.0, and CQI index2 is in a range with SINR [dB] 6.0 to 7.0. Are associated. FIG. 5 shows the correspondence between CQI Index and MCS. Specifically, QPSK is associated with CQI index 1 as a modulation method, and 78/1024 is associated with a channel coding rate (error rate coding rate; code rate). As the efficiency, 0.1523 is associated. The transmission efficiency is a value obtained by multiplying the channel coding rate by the modulation multilevel number M. When the modulation scheme is 64QAM, the modulation multilevel number M is 6 bits, and when the modulation scheme is QPSK, the modulation multilevel number M is 2 bits. Correspondence between CQI index and MCS shown in FIG. 5 is updated on the base station side or the mobile station side according to the channel state (transmission path state) such as fading and multipath environment, Optimized. In the LTE system, 16 stages of MCS levels are defined. When the transmission efficiency at MCS level 1 corresponding to CQI index 1 is compared with the transmission efficiency at MCS level 15 corresponding to CQI index 15, it is approximately 37 times. The difference (5.5547 / 0.1523 = 36.47 ...) is generated.

  In addition, an OFDM system used in an LTE system or the like performs communication using a large number of subcarriers simultaneously. At this time, the OFDM system used in the LTE system or the like can assign data signals to different mobile communication terminals for each subcarrier. An OFDM system used in an LTE system or the like is similar to a conventional FDM system in that a specific frequency is assigned to each mobile communication terminal. However, compared with the conventional FDM system, the OFDM system used in the LTE system or the like becomes a reception target when each mobile communication terminal simultaneously receives all OFDM subcarriers and performs OFDM signal reception processing. There is a major difference in taking out the subcarrier. Non-Patent Document 2 discloses a technique in which a group of subcarriers is named RB (Resorce Block) and radio resources are allocated to mobile communication terminals in units of RBs. That is, in the case of an LTE system, in order to efficiently perform localized transmission type radio resource allocation, consecutive subcarriers (for example, 12 subcarriers) are blocked and a minimum unit of radio resource allocation called RB (resource block) is defined. Is done. FIG. 6 shows a state where OFDM signals are composed of (n × m) subcarriers and grouped into nRBs composed of m subcarriers. In the case of FIG. 6, the user a uses a plurality of subcarrier groups set in the RB1 group, and the user b uses the plurality of subcarrier groups set in the RB2 group. The same applies hereinafter. Of course, one user can use a plurality of RBs. Therefore, the mobile communication terminal measures the radio channel quality for each band (RB), and transmits the radio channel quality measurement result to the base station 1 as channel state information (CQI information). The base station 1 determines a mobile communication terminal that transmits data to an individual information channel carrying transmission information, and selects a transmission format and a band (RB) to be used. A service form of a mobile communication system that performs high-speed data communication by performing adaptive modulation as described above for this user selection is generally a best-effort service. FIG. 7 is a diagram illustrating transmission timings of the base station 1 and the mobile communication terminal when performing adaptive modulation. The mobile communication terminal transmits the CQI to the base station 1 in the CQI time domain. The base station 1 determines a mobile communication terminal to be allocated to a frequency resource in the user selection time domain, and transmits user information and transmission format information of individual information channels and band information to be used in the control channel time domain to the mobile communication terminal Send to. The mobile communication terminal receives the dedicated information channel from the base station 1 based on the information put on this control channel.

T.Ue, S.Aampei, N.Morinaga and K.Hamaguchi, "Symbol Rate and Modulation Level-Controlled Adaptive Modulation / TDMA / TDD System for High-Bit-Rate Wireless Data Transmission", IEEE Trans. VT, pp. 1134-1147, vol. 47, no. 4, Nov. 1998 3GPP TS 36.213 V8.7.0 (2009-05)

  However, when a mobile communication terminal using a 3.5G mobile communication system that is currently in operation displays a channel state for the mobile communication terminal, as shown in FIG. Only the signal strength of the received signal is displayed using the indicator of about 4 steps used. This is a display method from before AMC was used, and it does not display the actual transmission rate directly, but reads the deterioration in reception quality only in places where reception quality is extremely poor, such as cell boundaries. Can be done. Therefore, the user cannot know the actual transmission rate because it is displayed that the reception quality is good in most areas when only the signal strength of the received signal is displayed using the indicator of about 4 steps. There was a problem.

  The present invention has been made in view of such a situation, and performs CQI measurement even during standby, suitably displays the communication quality, and performs wireless communication at a place where the communication quality is good for the user. An object of the present invention is to provide a mobile communication terminal and a communication quality display method that can promote the reduction of power consumption and the sector throughput of the terminal.

  In order to solve the above-described problems, a mobile communication terminal of the present invention includes a transmission / reception means for transmitting and receiving a radio signal between a mobile communication terminal and a base station belonging to the mobile communication system, a mobile communication terminal and a mobile communication terminal. A plurality of signal processing means for processing radio signals transmitted / received to / from a base station belonging to a mobile communication system, and a plurality of transmission lines between the mobile communication terminal and the base station belonging to the mobile communication system in advance. A mobile communication terminal is determined with a base station belonging to a mobile communication system as one of MCSs, which is a combination of a modulation scheme and an error correction coding rate, and is determined. Control means for controlling communication between the mobile station and a base station belonging to the mobile communication system, and reception for detecting the reception quality of radio signals from the base station belonging to the mobile communication system on which the mobile communication terminal is waiting MCS of MCS based on reception quality detected by reception quality detection means among a plurality of MCSs for each resource block included in a frequency band used by a quality detection means and a base station belonging to a mobile communication system When the mobile communication terminal is waiting for a base station belonging to the mobile communication system, the generation means for generating the channel state information including the level, and the channel state information for each resource block generated by the generation means Based on the calculation means for calculating the estimated MCS level in the mobile communication terminal when the mobile communication terminal performs data communication with the base station belonging to the mobile communication system, and displays the estimated MCS level calculated by the calculation means Display means.

  In order to solve the above-described problems, a mobile communication terminal of the present invention includes a transmission / reception means for transmitting and receiving a radio signal between a mobile communication terminal and a base station belonging to the mobile communication system, a mobile communication terminal and a mobile communication terminal. A plurality of signal processing means for processing radio signals transmitted / received to / from a base station belonging to a mobile communication system, and a plurality of transmission lines between the mobile communication terminal and the base station belonging to the mobile communication system in advance. A mobile communication terminal is determined with a base station belonging to a mobile communication system as one of MCSs, which is a combination of a modulation scheme and an error correction coding rate, and is determined. Control means for controlling communication between the mobile station and a base station belonging to the mobile communication system, and reception for detecting the reception quality of radio signals from the base station belonging to the mobile communication system on which the mobile communication terminal is waiting MCS of MCS based on reception quality detected by reception quality detection means among a plurality of MCSs for each resource block included in a frequency band used by a quality detection means and a base station belonging to a mobile communication system Generating means for generating channel state information including the level, frequency information bandwidth used by the base station belonging to the mobile communication system from broadcast information or downlink resource allocation information from the base station belonging to the mobile communication system, Detection means for detecting the number of other mobile communication terminals in data communication or negotiation during data communication with a base station on which the mobile communication terminal is awaited, a frequency bandwidth detected by the detection means, and a mobile object Based on the base station on which the communication terminal is waiting and the number of other mobile communication terminals in data communication or negotiation during data communication, Congestion degree calculating means for calculating a congestion degree related to a base station belonging to the mobile communication system, and each resource block generated by the generating means when the mobile communication terminal is waiting for a base station belonging to the mobile communication system An estimated MCS level calculating means for calculating an estimated MCS level at the mobile communication terminal when the mobile communication terminal performs data communication with a base station belonging to the mobile communication system based on the channel state information for each, and an estimated MCS Based on the estimated MCS level calculated by the level calculating means and the congestion degree calculated by the congestion degree calculating means, the estimated transmission rate when the mobile communication terminal performs data communication with the base station belonging to the mobile communication system Estimated transmission rate calculation means for calculating the estimated transmission rate, and display means for displaying the estimated transmission rate calculated by the estimated transmission rate calculation means. It is characterized by.

  In order to solve the above-described problem, a communication quality display method of the present invention includes a transmission / reception step for transmitting / receiving a radio signal between a mobile communication terminal and a base station belonging to the mobile communication system, a mobile communication terminal, and a mobile communication terminal. In accordance with a signal processing step for processing a radio signal transmitted / received to / from a base station belonging to a mobile communication system, and a transmission path state between the mobile communication terminal and the base station belonging to the mobile communication system, a plurality of A mobile communication terminal is determined with a base station belonging to a mobile communication system as one of MCSs, which is a combination of a modulation scheme and an error correction coding rate, and is determined. Control step for controlling communication between the mobile communication system and the base station belonging to the mobile communication system, and the reception quality of the radio signal from the base station belonging to the mobile communication system on which the mobile communication terminal is waiting Reception quality detected by the reception quality detection step in a plurality of MCSs for each resource block included in the frequency band used by the base station belonging to the mobile communication system and the reception quality detection step to detect Generating step of generating channel state information including MCS level of MCS based on the above, and each resource generated by the processing of the generating step when the mobile communication terminal is waiting for a base station belonging to the mobile communication system A calculation step for calculating an estimated MCS level in the mobile communication terminal when the mobile communication terminal performs data communication with a base station belonging to the mobile communication system based on channel state information for each block, and processing of the calculation step And a display step for displaying the estimated MCS level calculated by.

  In order to solve the above-described problem, a communication quality display method of the present invention includes a transmission / reception step for transmitting / receiving a radio signal between a mobile communication terminal and a base station belonging to the mobile communication system, a mobile communication terminal, and a mobile communication terminal. In accordance with a signal processing step for processing a radio signal transmitted / received to / from a base station belonging to a mobile communication system, and a transmission path state between the mobile communication terminal and the base station belonging to the mobile communication system, a plurality of A mobile communication terminal is determined with a base station belonging to a mobile communication system as one of MCSs, which is a combination of a modulation scheme and an error correction coding rate, and is determined. Control step for controlling communication between the mobile communication system and the base station belonging to the mobile communication system, and the reception quality of the radio signal from the base station belonging to the mobile communication system on which the mobile communication terminal is waiting Reception quality detected by the reception quality detection step in a plurality of MCSs for each resource block included in the frequency band used by the base station belonging to the mobile communication system and the reception quality detection step to detect The base station belonging to the mobile communication system uses the generation step of generating the channel state information including the MCS level of the MCS based on the broadcast information or the downlink resource allocation information from the base station belonging to the mobile communication system. Detected by the detection step of detecting the frequency bandwidth and the number of other mobile communication terminals that are in data communication or negotiation during data communication with the base station on which the mobile communication terminal is waiting, and detected by the processing of the detection step Frequency bandwidth and negotiation during data communication or data communication with the base station on which the mobile communication terminal is waiting A congestion degree calculating step for calculating a congestion degree related to a base station belonging to the mobile communication system based on the number of other mobile communication terminals in the mobile station, and a base station to which the mobile communication terminal belongs to the mobile communication system When the mobile communication terminal performs data communication with a base station belonging to the mobile communication system based on the channel state information for each resource block generated by the processing of the generation step Based on the estimated MCS level calculation step for calculating the estimated MCS level at the body communication terminal, the estimated MCS level calculated by the processing of the estimated MCS level calculation step, and the congestion level calculated by the congestion level calculation means Estimated transmission rate calculation step for calculating an estimated transmission rate when a mobile communication terminal performs data communication with a base station belonging to a mobile communication system. And a display step for displaying the estimated transmission rate calculated by the processing of the estimated transmission rate calculation step.

  According to the present invention, the CQI measurement is performed even during standby, the communication quality is suitably displayed, the user is encouraged to perform wireless communication in a place with good communication quality, the power consumption of the terminal and the sector throughput are reduced. Can be improved.

The conceptual diagram for demonstrating the AMC (adaptive modulation / demodulation coding) system employ | adopted as the conventional mobile communication system. The figure which shows the display method of the signal strength of the conventional received signal using the indicator of about four steps using RSSI. The block diagram which shows the structure of the conventional mobile communication terminal. The figure which shows the corresponding | compatible relationship between radio | wireless transmission path quality and CQI. The figure which shows the correspondence of CQI Index and MCS. The figure which shows a mode that an OFDM signal is comprised from the (nxm) subcarrier and is grouped into nRB which consists of m subcarriers. The figure which shows the transmission timing of a base station and a mobile communication terminal in performing adaptive modulation. The block diagram which shows the structure of the mobile communication terminal which concerns on 1st Embodiment of this invention. The flowchart explaining the MCS level display control process in the mobile communication terminal of FIG. The figure which shows an example of the calculation method of the estimated MCS level regarding the frequency band which the base station which belongs to a mobile communication system uses. The figure which shows the Min value and the Max value regarding the present estimated MCS level which a display part displays, and an estimated MCS level. The figure which shows the relationship between system bandwidth Fw, the number of users N, and the estimated transmission rate. The block diagram which shows the structure inside the mobile communication terminal which concerns on 2nd Embodiment of this invention. 14 is a flowchart for explaining transmission rate display control processing in the mobile communication terminal of FIG. 14 is a flowchart for explaining transmission rate display control processing in the mobile communication terminal of FIG. The figure which shows the Min value and Max value regarding the present estimated transmission rate which an indicator displays, and an estimated transmission rate. 14 is a flowchart for explaining transmission rate display control processing in the mobile communication terminal of FIG. 14 is a flowchart for explaining transmission rate display control processing in the mobile communication terminal of FIG. (A) And (B) is a figure which shows the histogram of the MCS level regarding another mobile communication terminal. The figure which shows the mode which a mobile communication terminal can select regarding a download. 14 is a flowchart for explaining download mode setting processing in the mobile communication terminal of FIG. 8 or FIG. 13. The flowchart explaining the data download control process in the mobile communication terminal of FIG. 14 is a flowchart for explaining data download control processing in the mobile communication terminal of FIG. Explanatory drawing explaining the setting method which sets the reference value regarding estimated download time according to the cover area size of a base station. Explanatory drawing explaining the setting method which sets the reference value regarding estimated download time according to the frequency | count per unit time of a handover. The block diagram which shows the structure inside the mobile communication terminal which concerns on 4th Embodiment of this invention. The flowchart explaining the communication quality MAP display process in the mobile communication terminal of FIG. The figure which shows the communication quality MAP which a control part produces.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

[First Embodiment]
FIG. 8 shows the configuration of the mobile communication terminal 101 according to the first embodiment of the present invention. As shown in FIG. 8, the mobile communication terminal 101 includes a transmission / reception antenna 111, a radio unit 112, a reception signal processing unit 113, a reception data processing unit 114, a PCM codec 115, a reception amplifier 116, a receiver 117, a transmission amplifier 118, Microphone 119, control unit 120, RSSI (Received Signal Strength Indicator) measurement unit 121, operation unit 122, display unit 123, storage unit 124, SINR (Signal-to-interference-plus-Noise Ratio) A measurement unit 125, a CQI (Channel Quality Indicator) information generation unit 126, a CQI information control unit 127, a CQI information storage unit 128, a transmission data processing unit 129, and a transmission signal processing unit 130 are provided.

  The transmission / reception antenna 111 transmits radio waves of the mobile communication system to which the mobile communication terminal 101 corresponds, or receives radio waves of the mobile communication system to which the mobile communication terminal 1 corresponds. A transmission / reception duplexer (not shown) includes a circulator, a duplexer, and the like, and transmits radio waves received (received) by the transmission / reception antenna 111 to the radio unit 112. Further, the transmission / reception duplexer transmits the signal input from the wireless unit 112 to the transmission / reception antenna 111. The radio reception unit 112 includes a bandpass filter, a gain adjustment circuit, an A / D converter, and the like, receives a radio signal having a carrier frequency instructed from the control unit 120, and a local oscillation signal output from the frequency synthesizer. Mixing and frequency conversion (down-conversion) into an intermediate frequency signal, and orthogonal demodulation of the down-converted intermediate frequency signal generates a reception baseband signal. The band pass filter of the radio reception unit 112 receives a radio signal transmitted from a base station belonging to the mobile communication system, and removes noise outside the desired band from the received signal. In addition, the gain adjustment circuit of the wireless reception unit 112 adjusts the signal amplitude to be handled by an A / D converter provided at the subsequent stage of the gain adjustment circuit. The A / D converter of the wireless reception unit 112 converts the signal that has passed through the band-pass filter into a baseband digital signal.

  The reception signal processing unit 113 performs baseband processing on the reception baseband signal (reception baseband digital signal) output from the wireless reception unit 112 according to the mobile communication system to which the mobile communication terminal 101 is connected. The reception signal processing unit 113 includes a demodulation unit 131, a rate conversion unit 132, a decoding unit 133, and an error detection unit 134.

  The demodulation unit 131 includes an FFT unit (time / frequency conversion circuit), a frequency channel separation unit, a descrambling unit, a channel estimation unit, and a channel equalization unit, and performs multicarrier demodulation by OFDM. Specifically, after a guard interval is removed by a GI removal unit (not shown), a baseband digital signal is converted from a time domain signal to a frequency domain by an FFT unit (fast Fourier transform unit, that is, a time / frequency conversion circuit). Signal, that is, a signal for each subcarrier. The FFT unit outputs the output signal divided for each subcarrier to the frequency channel separation unit. The frequency channel separation unit separates the pilot channel signal and the data channel signal respectively assigned to the subcarriers. The frequency channel separation unit outputs each separated signal (pilot channel signal and data channel signal) to the descrambling unit. The descrambling unit performs descrambling using a scrambling code sequence applied by the OFDM transmitter (base station) for each signal, and outputs the descrambled signal to the channel equalization unit. It is assumed that the scrambling code sequence applied at the base station is known on the mobile communication terminal 101 side as an OFDM receiver. The frequency channel separation unit outputs the separated pilot channel signal to the channel estimation unit. The channel estimator performs channel estimation by averaging or interpolating pilot channel signals. The channel estimation unit outputs a channel estimation value indicating the channel response to the channel equalization unit. The channel equalization unit performs channel equalization on each data channel signal using the channel estimation value from the channel estimation unit. The time / frequency conversion circuit may use DFT (Discrete Fourier Transform). Demodulation section 131 outputs the data channel signal after channel equalization to rate conversion section 132.

  The rate conversion unit 132 converts the data channel signal after channel equalization based on the channel coding rate (channel coding rate) R included in the channel information acquired in advance from the base station, and performs data after channel equalization. Remove redundant parts from the channel signal. Here, “channel coding rate R” means original transmission data before error correction coding processing (processing for adding bits necessary for error correction) and error correction coding processing for the transmission data. Means the ratio of the amount of information to the actual transmission data that the base station transmits to the mobile communication terminal 101 after applying. For example, when error correction coding processing for adding 1 bit for error correction is performed on original transmission data of 3 bits and channel coding is performed to 4 bits, the channel coding rate R is 3/4 (= 75%). It becomes. Assuming that the channel coding rate R is 3/4, the rate conversion unit 132 rate-converts the data channel signal to 3/4 based on the channel coding rate R, and is added to the original transmission data in advance. Remove redundant parts. Rate conversion section 132 outputs the data channel signal after the rate conversion to decoding section 133.

  Decoding section 133 performs subcarrier demodulation on the data channel signal after rate conversion based on a modulation scheme (digital modulation scheme such as QPSK) included in channel information acquired in advance from the base station, and performs subcarrier demodulation. The subsequent data channel signal is output to error detection section 134. The error detection unit 134 performs channel decoding (error correction decoding) on the data channel signal after subcarrier demodulation, and reproduces a bit string (downlink transmission data bit string) that is a source of the data signal. Reception signal processing section 113 outputs the downlink transmission data bit string to reception data processing section 114.

  The reception data processing unit 114 converts the baseband signal that has been baseband processed by the reception signal processing unit 113 into data and voice. The control unit 120 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. The CPU of the control unit 120 executes various processes according to various application programs and control programs including an operating system (OS) loaded into the RAM from the program or the storage unit 25, and performs various processes. The mobile communication terminal 101 is comprehensively controlled by generating a control signal and supplying it to each unit. The RAM appropriately stores data necessary for the CPU to execute various processes. Specifically, the control unit 120 has a control function for realizing voice communication and data communication by the mobile communication system, controls the carrier frequency used by the radio unit 112, and is based on the reception result at the radio unit 112. To search for pilot signals.

  The mobile communication terminal 101 includes a reception amplifier 116, a receiver 117 that amplifies and outputs a reception voice signal, a transmission amplifier 118, a microphone 119 that inputs a transmission voice signal, an operation unit 122 that receives a request from a user, and reception data. A display unit 123 that displays a base image is provided. The storage unit 124 includes, for example, a flash memory element that is an electrically rewritable and erasable nonvolatile memory, an HDD (Hard Disc Drive), and the like. Data group, control program and control data of the mobile radio terminal 1, and identification information uniquely assigned to the mobile radio terminal 1 or the user. In addition to this, the storage unit 124 appropriately stores telephone directory data in which names and telephone numbers are associated, data acquired by data communication, and downloaded data. The mobile communication terminal 101 also includes a power supply circuit that generates a predetermined operating power supply voltage Vcc based on the output of the battery and supplies it to each circuit unit, and a clock circuit (timer) that measures the current time.

  The RSSI (received signal strength) measuring unit 121 measures the received signal strength in the received signal processing unit 113 and outputs the measurement result to the control unit 120. The SINR measurement unit 125 measures the radio transmission path quality (SINR) related to the received signal from the received signal processing unit 113 and outputs the measurement result to the CQI information generation unit 126. Note that the radio transmission path quality related to the received signal may be the SIR of the received signal. The CQI information generation unit 126 determines a receivable transmission format (combination of modulation scheme and channel coding rate (MCS)) based on the measurement result by the SINR measurement unit 125, and is determined. Channel state information (CQI information: Channel Quality Indicator information) is generated based on the transmission format (combination of modulation scheme and error correction coding rate). This channel state information (CQI information) includes a CQI Index indicating a combination (MCS) of a modulation scheme and an error correction coding rate, and an MCS level corresponding to the CQI Index. CQI information generation section 126 outputs channel state information (CQI information) to CQI information control section 127 and transmission signal processing section 130. The channel state information is transmitted to the base station via the transmission signal processing unit 130 and the radio unit 112.

  The CQI information control unit 127 acquires the channel state information (CQI information) from the CQI information generation unit 126, and stores the current estimation stored in the CQI information storage unit 128 at regular intervals based on the acquired channel state information. The Min value and the Max value related to the MCS level and the estimated MCS level are initialized or updated. The CQI information storage unit 128 stores a current estimated MCS level and a Min value and a Max value related to the estimated MCS level.

  The transmission data processing unit 129 performs transmission baseband processing for transmitting communication data to a base station belonging to a mobile communication system that can be used by the mobile communication terminal 101. The transmission data processing unit 129 includes at least a coding unit 141 and a modulation unit 142. The encoding unit 141 performs subcarrier modulation on transmission data based on a modulation scheme (digital modulation scheme such as QPSK) included in channel information acquired in advance from a base station, and transmits transmission data after subcarrier modulation. Output to the modulation unit 142. Modulator 142 performs multicarrier modulation by OFDM on the transmission data after subcarrier modulation. Specifically, the modulation unit 142 includes an IFFT unit, and generates an OFDM signal by converting a frequency domain signal into a time domain signal. The OFDM signal generated by the IFFT unit is added with a guard interval (GI) and output to the radio unit 112.

  The MCS level display control process in the mobile communication terminal 101 of FIG. 8 will be described with reference to the flowchart of FIG. In FIG. 9, it is assumed that the mobile communication terminal 101 has started a standby mode, and the mobile communication terminal 101 is one of base stations belonging to a mobile communication system (such as an OFDMA mobile communication system). And waiting. Here, the “standby mode” means that the mobile communication terminal 101 has been registered as a mobile station with respect to the mobile communication network, but there is no data to be communicated with the mobile communication terminal 101, so data communication with the base station is not possible. This means that paging is performed at a predetermined cycle (paging cycle) and whether or not there is an incoming call is confirmed.

  In step S1, the control unit 120 controls the radio unit 112 and the reception signal processing unit 113 to start a standby mode for any base station belonging to the mobile communication system. In step S <b> 2, the control unit 120 is configured to measure the SINR in all resource blocks included in the frequency band used by the base station belonging to the mobile communication system to which the mobile communication terminal 101 is connected. Unit 112 and reception signal processing unit 113 are controlled. The SINR measurement unit 125 is used by a base station belonging to a mobile communication system to which the mobile communication terminal 101 is connected at a paging cycle (paging channel cycle) or a cycle that is an integer multiple of the paging cycle (such as 2 or 3). At each RB (resource block) included in the frequency band, the wireless transmission path quality (SINR) related to the received signal (received signal related to a known signal such as a pilot signal) from the received signal processing unit 113 is measured. The measurement result is output to the CQI information generation unit 126. The CQI information generation unit 126 determines a receivable MCS based on the measurement result by the SINR measurement unit 125 in each RB included in the frequency band used by the base station belonging to the mobile communication system, and determines the determined transmission format Based on (combination of modulation scheme and error correction coding rate), channel state information (CQI information) is generated. The CQI information for each RB includes a CQI Index indicating a combination (MCS) of a modulation scheme and an error correction coding rate, and an MCS level corresponding to the CQI Index. CQI information generation section 126 outputs CQI information for each RB to CQI information control section 127.

  In step S3, the CQI information control unit 127 acquires CQI information for each RB included in the frequency band used by the base station belonging to the mobile communication system to which the mobile communication terminal 101 is connected, and acquires each acquired RB. Based on the CQI information for each, an estimated MCS level relating to a frequency band used by a base station belonging to the mobile communication system is calculated. Here, the “estimated MCS level” refers to an MCS level estimated when the mobile communication terminal 101 performs data communication with a base station belonging to the mobile communication system in a current transmission path state. In the case of data communication with a base station belonging to a mobile communication system, the MCS is determined by negotiation with the base station, so the estimated MCS level is used for data communication only in the current transmission path state. This is the estimated MCS level. Specifically, the CQI information control unit 127 uses the average of the MCS levels of all RBs included in the frequency band used by the base station belonging to the mobile communication system as the frequency used by the base station belonging to the mobile communication system. Calculated as the estimated MCS level for the band. FIG. 10 shows an example of a method for calculating an estimated MCS level related to a frequency band used by a base station belonging to a mobile communication system. In the case of FIG. 10, the MCS level in RB1 is “6”, the MCS level in RB2 is “8”, and so on. The average of the MCS levels of RB1 to RB8 included in the frequency band used by the base station belonging to the mobile communication system is about 5 (= 43/8). Therefore, in the case of FIG. 10, the CQI information control unit 127 calculates the estimated MCS level related to the frequency band used by the base station belonging to the mobile communication system as “5”. Note that the CQI information control unit 127 may use the maximum MCS level among all RBs as the estimated MCS level related to the frequency band used by the base station belonging to the mobile communication system. Specifically, in the case of FIG. 10, the CQI information control unit 127 uses the maximum MCS level 8 of all RBs as the estimated MCS level related to the frequency band used by the base station belonging to the mobile communication system.

  Also, the CQI information control unit 127 updates the current estimated MCS level stored in the CQI information storage unit 128 based on the calculated estimated MCS level. The CQI information storage unit 128 stores the current estimated MCS level according to the control of the CQI information control unit 127. For example, when the calculated estimated MCS level is “10”, the current estimated MCS level stored in the CQI information storage unit 128 is updated to “MCS level 10”.

  In step S4, the CQI information control unit 127 reads the Max value related to the estimated MCS level (Max value related to the past estimated MCS level measured by the mobile communication terminal 101 so far) stored in the CQI information storage unit 128, It is determined whether or not the calculated estimated MCS level is larger than the Max value related to the read estimated MCS level. For example, when the calculated estimated MCS level is “10” and the Max value related to the estimated MCS level stored in the CQI information storage unit 128 is “12”, the CQI information control unit 127 calculates the estimated It is determined that the MCS level is smaller than the Max value relating to the read estimated MCS level. On the other hand, for example, when the calculated estimated MCS level is “13” and the Max value regarding the estimated MCS level stored in the CQI information storage unit 128 is “12”, the CQI information control unit 127 is calculated. It is determined that the estimated MCS level is larger than the Max value related to the read estimated MCS level. When the CQI information control unit 127 determines in step S4 that the calculated estimated MCS level is greater than the Max value related to the read estimated MCS level, the CQI information control unit 127 performs the CQI information storage unit 128 in step S5. Is updated to the calculated estimated MCS level. On the other hand, when the CQI information control unit 127 determines in step S4 that the calculated estimated MCS level is equal to or less than the Max value related to the read estimated MCS level, the CQI information control unit 127 skips the process of step S5. . Thereby, the Max value of the estimated MCS level stored in the CQI information storage unit 128 is not updated and is maintained as it is.

  In step S6, the CQI information control unit 127 reads the Min value related to the estimated MCS level (the Min value related to the past estimated MCS level measured by the mobile communication terminal 101 so far) stored in the CQI information storage unit 128, It is determined whether or not the calculated estimated MCS level is smaller than the Min value related to the read estimated MCS level. For example, when the calculated estimated MCS level is “10” and the Min value related to the estimated MCS level stored in the CQI information storage unit 128 is “2”, the CQI information control unit 127 calculates the estimated It is determined that the MCS level is larger than the Min value relating to the read estimated MCS level. On the other hand, for example, when the calculated estimated MCS level is “1” and the Min value related to the estimated MCS level stored in the CQI information storage unit 128 is “2”, the CQI information control unit 127 is calculated. It is determined that the estimated MCS level is smaller than the Min value relating to the read estimated MCS level. When the CQI information control unit 127 determines in step S6 that the calculated estimated MCS level is smaller than the Min value related to the read estimated MCS level, the CQI information control unit 127 performs the CQI information storage unit 128 in step S7. Is updated to the calculated estimated MCS level. On the other hand, when the CQI information control unit 127 determines in step S6 that the calculated estimated MCS level is equal to or greater than the Min value related to the read estimated MCS level, the CQI information control unit 127 skips the process of step S7. Thereby, the Min value of the estimated MCS level stored in the CQI information storage unit 128 is not updated and is maintained as it is.

  As described above, the CQI information storage unit 128 updates the Min value and the Max value related to the current estimated MCS level and the estimated MCS level according to the control of the CQI information control unit 127 by the processing of steps S3 to S7. For example, when the calculated estimated MCS level is “10” and the Min value and the Max value relating to the estimated MCS level are not changed, only the current estimated MCS level stored in the CQI information storage unit 128 is “MCS level 10”. Is updated.

  In step S8, the control unit 120 reads the Min value and the Max value related to the current estimated MCS level and the estimated MCS level stored in the CQI information storage unit 128, and relates to the read current estimated MCS level and estimated MCS level. The display on the display unit 123 is updated using the Min value and the Max value. Thus, the current estimated MCS level displayed on the display unit 123 and the Min value and the Max value related to the estimated MCS level displayed on the display unit 123 while the mobile communication terminal 101 is waiting with the base station are stored in the CQI information storage unit 128. The estimated MCS level and the Min value and the Max value related to the estimated MCS level are updated every predetermined cycle (a paging cycle or a cycle that is an integral multiple of the paging cycle). FIG. 11 shows the current estimated MCS level displayed on the display unit 123, and the Min value and the Max value related to the estimated MCS level. In the case of FIG. 11, “10” is displayed as the current estimated MCS level, “2” is displayed as the Min value related to the estimated MCS level, and “12” is displayed as the Max value related to the estimated MCS level. In step S9, the control unit 120 determines whether to start data communication with the base station on which the mobile communication terminal 101 is waiting. When the control unit 120 determines in step S9 that the mobile communication terminal 101 does not start data communication with the base station on which the mobile communication terminal 101 is waiting, the process returns to step S2, and the mobile communication terminal 101 continues the standby mode, In step S2, CQI information for each RB is generated for each paging cycle or an integer multiple of the paging cycle. Based on the generated CQI information for each RB, the current estimated MCS level and the Min value for the estimated MCS level The Max value is updated as appropriate. Note that the current estimated MCS level stored in the CQI information storage unit 128 and the Min value and the Max value related to the estimated MCS level are initialized at a constant cycle (for example, a cycle of 30 minutes). Note that the current estimated MCS level stored in the CQI information storage unit 128 and the Min value and Max value related to the estimated MCS level are initialized arbitrarily by the user, and the mobile communication terminal 101 specifies the specified cycle. You may make it set as an initialization period.

  On the other hand, when the control unit 120 determines in step S9 to start data communication with the base station on which the mobile communication terminal 101 is waiting, the control unit 120 determines in step S10 that the radio unit 112, the received signal processing unit 113, and the SINR. It controls the measurement unit 125, the CQI information generation unit 126, and the transmission signal processing unit 130, negotiates with the base station, and determines the MCS used for communication. Specifically, the mobile communication terminal 101 transmits CQI information to the base station, and the base station transmits user information and transmission format information of the channel of the individual information and band information to be used to the mobile communication terminal 101. The mobile communication terminal 101 receives the individual information channel from the base station based on the information put on the control channel via the radio unit 112 and the received signal processing unit 113, and the control unit 120 Acquires this dedicated information channel and recognizes the MCS used for communication. The control unit 120 of the mobile communication terminal 101 controls the radio unit 112, the reception signal processing unit 113, and the transmission signal processing unit 130, and starts data communication using the MCS determined by negotiation with the base station.

  In step S11, the CQI information control unit 127 performs the control of the control unit 120 to determine the MCS level determined between the mobile communication terminal 101 and the base station, and the current estimated MCS stored in the CQI information storage unit 128. It is determined whether or not the level (current estimated MCS level displayed by the display unit 123) is different. For example, the estimated MCS level determined between the mobile communication terminal 101 and the base station is “MCS level 8”, and the current estimated MCS level stored in the CQI information storage unit 128 is “MCS level 10”. In some cases, the CQI information control unit 127 follows the control of the control unit 120, the estimated MCS level determined between the mobile communication terminal 101 and the base station, and the current stored in the CQI information storage unit 128. It is determined that the estimated MCS level is different.

  When the CQI information control unit 127 determines in step S11 that the MCS level determined between the mobile communication terminal 101 and the base station is different from the current estimated MCS level stored in the CQI information storage unit 128 The CQI information control unit 127 is stored in the CQI information storage unit 128 in step S12 based on the MCS level determined between the mobile communication terminal 101 and the base station according to the control of the control unit 120. The estimated MCS level (current estimated MCS level displayed by the display unit 123) is updated. For example, the MCS level determined between the mobile communication terminal 101 and the base station is “MCS level 8”, and the current estimated MCS level stored in the CQI information storage unit 128 is “MCS level 10”. In this case, the current estimated MCS level stored in the CQI information storage unit 128 is updated to “MCS level 8”. Thereby, when the mobile communication terminal 101 performs data communication with the base station, the mobile communication terminal 101 can match the MCS level determined with the base station, and the communication quality during data communication can be suitably displayed.

  On the other hand, the MCS level determined by the CQI information control unit 127 between the mobile communication terminal 101 and the base station in step S11 is the same as the current estimated MCS level stored in the CQI information storage unit 128. Is determined, the process of step S12 is skipped.

  In step S13, the CQI information control unit 127 reads the Max value related to the estimated MCS level stored in the CQI information storage unit 128, and the MCS level determined between the mobile communication terminal and the base station is read. It is determined whether or not the value is larger than the Max value related to the estimated MCS level. For example, when the MCS level determined between the mobile communication terminal and the base station is “10”, when the Max value related to the estimated MCS level stored in the CQI information storage unit 128 is “12”, the CQI The information control unit 127 determines that the MCS level determined between the mobile communication terminal and the base station is smaller than the Max value related to the read estimated MCS level. On the other hand, for example, when the MCS level determined between the mobile communication terminal and the base station is “13”, the Max value related to the estimated MCS level stored in the CQI information storage unit 128 is “12”. The CQI information control unit 127 determines that the MCS level determined between the mobile communication terminal and the base station is larger than the Max value related to the read estimated MCS level. When the CQI information control unit 127 determines in step S13 that the MCS level determined between the mobile communication terminal and the base station is larger than the Max value related to the read estimated MCS level, the CQI information control unit 127 In step S14, the Max value of the estimated MCS level stored in the CQI information storage unit 128 is updated to the MCS level determined between the mobile communication terminal and the base station. On the other hand, when the CQI information control unit 127 determines in step S13 that the MCS level determined between the mobile communication terminal and the base station is equal to or less than the Max value related to the read estimated MCS level, CQI information control is performed. The unit 127 skips the process of step S14. Thereby, the Max value of the estimated MCS level stored in the CQI information storage unit 128 is not updated and is maintained as it is.

  In step S15, the CQI information control unit 127 reads the Min value related to the estimated MCS level stored in the CQI information storage unit 128, and the MCS level determined between the mobile communication terminal and the base station is read out. It is determined whether the value is smaller than the Min value related to the estimated MCS level. For example, when the MCS level determined between the mobile communication terminal and the base station is “10”, the Min value related to the estimated MCS level stored in the CQI information storage unit 128 is “2”. The CQI information control unit 127 determines that the MCS level determined between the mobile communication terminal and the base station is larger than the Min value related to the read estimated MCS level. On the other hand, for example, when the MCS level determined between the mobile communication terminal and the base station is “1”, the Min value related to the estimated MCS level stored in the CQI information storage unit 128 is “2”. The CQI information control unit 127 determines that the MCS level determined between the mobile communication terminal and the base station is smaller than the Min value related to the read estimated MCS level. When the CQI information control unit 127 determines in step S15 that the MCS level determined between the mobile communication terminal and the base station is smaller than the Min value related to the read estimated MCS level, the CQI information control unit 127 In step S16, the Min value of the estimated MCS level stored in the CQI information storage unit 128 is updated to the MCS level determined between the mobile communication terminal and the base station. On the other hand, when the CQI information control unit 127 determines in step S15 that the MCS level determined between the mobile communication terminal and the base station is greater than or equal to the Min value related to the read estimated MCS level, the CQI information control unit 127 Skips the process of step S16. Thereby, the Min value of the estimated MCS level stored in the CQI information storage unit 128 is not updated and is maintained as it is.

  In step S <b> 17, the control unit 120 reads the current estimated MCS level and the Min value and the Max value related to the estimated MCS level stored in the CQI information storage unit 128, and relates to the read current estimated MCS level and estimated MCS level. The display on the display unit 123 is updated using the Min value and the Max value. Thereby, when the mobile communication terminal 101 starts data communication with the base station, the current estimated MCS level displayed on the display unit 123 and the Min value and the Max value related to the estimated MCS level are stored in the CQI information storage unit 128. The current estimated MCS level to be stored and the Min value and the Max value related to the estimated MCS level are updated.

  In step S18, the control unit 120 determines whether to end data communication with the base station on which the mobile communication terminal 101 is waiting, and performs data communication with the base station on which the mobile communication terminal 101 is waiting. The mobile communication terminal 101 waits until it is determined to end, and performs data communication with the base station. If the control unit 120 determines in step S18 that the data communication with the base station on which the mobile communication terminal 101 is waiting is terminated, the process returns to step S1, and the control unit 120 includes the radio unit 112 and the received signal processing unit. 113 is started, the standby mode is started for any of the base stations belonging to the mobile communication system, and then the processing after step S2 is started.

  As described above, the mobile communication terminal 101 according to the first embodiment of the present invention transmits and receives radio signals between the mobile communication terminal and the base station belonging to the mobile communication system, and the mobile communication terminal and the mobile A modulation method for processing a radio signal transmitted / received to / from a base station belonging to a communication system, and a plurality of modulation schemes determined in advance according to a transmission path state between the mobile communication terminal and the base station belonging to the mobile communication system And a base station belonging to the mobile communication system as one of MCSs that are combinations of error correction coding rates, and using the determined MCS, the mobile communication terminal and the mobile communication system Controls communication with base stations belonging to the mobile communication terminal, detects reception quality of radio signals from base stations belonging to the mobile communication system on which the mobile communication terminal is waiting, and uses the base stations belonging to the mobile communication system To lap For each resource block included in several bands, channel state information including an MCS level of MCS based on detected reception quality among a plurality of MCSs is generated, and the mobile communication terminal belongs to the mobile communication system Mobile communication terminal when mobile communication terminal performs data communication with base station belonging to mobile communication system based on channel state information generated for each resource block when waiting for base station The estimated MCS level at can be calculated and the calculated estimated MCS level can be displayed. Thereby, the mobile communication terminal 101 according to the first embodiment of the present invention performs CQI measurement even during standby, displays the CQI index corresponding to the MCS in real time, and favorably improves communication quality (reception quality). Can be displayed. Then, the user can recognize where the transmission path condition is actually good, prompt the user to perform wireless communication in a place with good reception quality, and reduce the power consumption of the mobile communication terminal 101. And sector throughput can be improved. Moreover, the mobile communication system can perform data transmission using MCS with good transmission efficiency, and can improve the frequency utilization efficiency.

[Second Embodiment]
By the way, in the case of the first embodiment of the present invention, the mobile communication terminal 101 displays the current estimated MCS level and the Min value and the Max value related to the MCS level when waiting for the base station or starting data communication. Will be updated accordingly. Thereby, the mobile communication terminal 101 can perform CQI measurement even during standby, and can preferably display the communication quality (reception quality). Other communication quality display methods (reception quality display methods) are considered as follows. That is, the transmission rate when the mobile communication terminal 101 starts data communication is predicted based on broadcast information from the base station, downlink resource allocation information, and the like, and the predicted transmission rate is displayed as reception quality. Specifically, the mobile communication terminal 101 performs CQI measurement (generates CQI information) at the paging cycle or an integer multiple of the paging cycle while waiting with the base station, and the current estimated MCS level and estimated MCS level. The display of the Min value and the Max value relating to the base station is appropriately updated, and the terminal is notified based on broadcast information or downlink resource allocation information (including information on the system band and information on the number of users based on the user ID) from the base station The allocated radio resource amount is estimated, and the transmission rate (transmission rate) is predicted and displayed from the MCS estimated from the measured CQI and the estimated resource amount. FIG. 12 shows the relationship between the system bandwidth (frequency bandwidth) Fw, the number of users N, and the predicted transmission rate. As shown in FIG. 12, the mobile communication terminal 101 performs data communication with the base station as the system bandwidth (frequency bandwidth) used by the base station to which the mobile communication terminal 101 is connected becomes relatively wide. As the number of mobile communication terminals 101 connected to the base station (that is, the number of users) decreases, the amount of radio resources that the base station allocates per terminal increases. Therefore, the predicted transmission rate when the mobile communication terminal 101 performs data communication with the base station increases.

  On the other hand, as the system bandwidth (frequency bandwidth) used by the base station to which the mobile communication terminal 101 is connected becomes relatively narrow, transmission predicted when the mobile communication terminal 101 performs data communication with the base station Since the rate decreases and the number of mobile communication terminals 101 connected to the base station (that is, the number of users) increases, the amount of radio resources that the base station allocates per terminal decreases. When the communication terminal 101 performs data communication with the base station, a predicted transmission rate is lowered. Hereinafter, a transmission rate prediction method according to the second embodiment of the present invention will be described.

  FIG. 13 shows the internal configuration of the mobile communication terminal 101 according to the second embodiment of the present invention. The configuration of FIG. 13 is basically the same as the configuration of the mobile communication terminal 101 according to the first embodiment of the present invention shown in FIG. Components corresponding to those in FIG. 8 are denoted by the same reference numerals, and descriptions of components other than the different components are omitted.

  The allocation information acquisition unit 151 acquires broadcast information or downlink resource allocation information (including information related to the system band and information related to the number of users based on the user ID) from the received signal processing unit 113, and the base station System bandwidth Fw, number of users N, or other movement during data communication or negotiation during data communication with the base station on which the mobile communication terminal 101 is waiting, from the broadcast information or downlink resource allocation information from The body communication terminal 101 detects the MCS determined with the base station. The allocation information acquisition unit 151 transmits information about the detected system bandwidth Fw, the number of users N, or MCS determined by other mobile communication terminals 101 to the base station, as a transmission rate (transmission rate) calculation unit 152. Output to.

  The transmission rate calculation unit 152 acquires information from the allocation information acquisition unit 151 (system bandwidth Fw, the number of users N, or information related to MCS determined by the other mobile communication terminal 101 with the base station). The congestion degree Tr (= system bandwidth Fw / number of users N) is calculated. Also, the transmission rate calculation unit 152 calculates an estimated estimated transmission rate based on the estimated MCS level related to the frequency band used by the base station belonging to the mobile communication system from the CQI information control unit 127 and the congestion degree Tr. The calculated estimated transmission rate is output to the transmission rate information storage unit 153. The transmission rate information storage unit 153 stores the current estimated transmission rate and the Min value and the Max value related to the estimated transmission rate.

  The transmission rate display control processing in the mobile communication terminal 101 in FIG. 13 will be described with reference to the flowcharts in FIGS. 14 and 15. 14 and 15, it is assumed that the mobile communication terminal 101 has started the standby mode, and the mobile communication terminal 101 is one of those belonging to a mobile communication system (such as an OFDMA mobile communication system). Waiting for a base station.

  In step S101, the control unit 120 controls the radio unit 112 and the received signal processing unit 113 to start a standby mode for any base station belonging to the mobile communication system. In step S102, the mobile communication terminal 101 receives a broadcast channel constantly transmitted from the base station. The allocation information acquisition unit 151 acquires broadcast information or downlink resource allocation information (including information related to the system band and information related to the number of users based on the user ID) from the received signal processing unit 113, and the base station The system bandwidth Fw is detected from the broadcast information or downlink resource allocation information. In step S103, the allocation information acquisition unit 151 performs data communication or data communication with the base station on which the mobile communication terminal 101 is waiting based on the broadcast ID from the base station or the user ID included in the downlink resource allocation information. The number of other mobile communication terminals 101 during negotiation (that is, the number of users N) is detected.

  In step S104, the control unit 120 wirelessly measures SINRs in all resource blocks included in a frequency band used by a base station belonging to the mobile communication system to which the mobile communication terminal 101 is connected. Unit 112 and reception signal processing unit 113 are controlled. The SINR measurement unit 125 is included in a frequency band used by a base station belonging to a mobile communication system to which the mobile communication terminal 101 is connected, with a paging cycle or an integer multiple of a paging cycle (such as 2 or 3). In each RB (resource block), the radio channel quality (SINR) related to the received signal (received signal related to a known signal such as a pilot signal) from the received signal processing unit 113 is measured, and the measurement result in each RB is represented as CQI information. The data is output to the generation unit 126. The CQI information generation unit 126 determines a receivable MCS based on the measurement result by the SINR measurement unit 125 in each RB included in the frequency band used by the base station belonging to the mobile communication system, and determines the determined transmission format Based on (combination of modulation scheme and error correction coding rate), channel state information (CQI information) is generated. The CQI information for each RB includes a CQI Index indicating a combination (MCS) of a modulation scheme and an error correction coding rate, and an MCS level corresponding to the CQI Index. CQI information generation section 126 outputs CQI information for each RB to CQI information control section 127.

  In step S105, the CQI information control unit 127 acquires CQI information for each RB included in the frequency band used by the base station belonging to the mobile communication system to which the mobile communication terminal 101 is connected, and acquires each acquired RB. Based on the CQI information for each, an estimated MCS level relating to a frequency band used by a base station belonging to the mobile communication system is calculated. Note that the calculation method of the estimated MCS level related to the frequency band used by the base station belonging to the mobile communication system in step S105 is basically the same as the calculation method in step S3 of FIG. 9, and the description thereof will be repeated. I will omit it. In step S106, the transmission rate calculation unit 152 acquires the system bandwidth Fw and the number of users N detected by the allocation information acquisition unit 151, and based on the acquired system bandwidth Fw and the number of users N, the congestion degree Tr ( = System bandwidth Fw / number of users N) is calculated. This congestion degree Tr indicates the degree of congestion of the base station on which the mobile communication terminal 101 is waiting.

  In step S107, the transmission rate calculation unit 152 predicts an estimated transmission rate (estimated transmission rate) Er based on the estimated MCS level related to the frequency band used by the base station belonging to the mobile communication system and the congestion degree Tr. Is calculated. Here, the “estimated transmission rate” refers to a transmission rate estimated when the mobile communication terminal 1010 performs data communication with a base station belonging to the mobile communication system in a current transmission line state. Also, the transmission rate calculation unit 152 updates the current estimated transmission rate stored in the transmission rate information storage unit 153 based on the calculated estimated transmission rate (predicted transmission rate). The transmission rate information storage unit 153 stores the current estimated transmission rate according to the control of the transmission rate calculation unit 152. For example, when the calculated estimated transmission rate is “1.2 Mbps”, the current estimated transmission rate stored in the transmission rate information storage unit 153 is updated to “1.2 Mbps”.

  In step S108, the transmission rate calculation unit 152 reads the Max value related to the estimated transmission rate stored in the transmission rate information storage unit 153 (Max value related to the past estimated transmission rate predicted by the mobile communication terminal 101 so far). Then, it is determined whether or not the calculated estimated transmission rate is larger than the Max value regarding the read estimated transmission rate. For example, when the calculated estimated transmission rate is “1.2 Mbps” and the Max value related to the estimated transmission rate stored in the transmission rate information storage unit 153 is “3.4 Mbps”, the transmission rate calculation unit 152 Then, it is determined that the calculated estimated transmission rate is smaller than the Max value regarding the read estimated transmission rate. On the other hand, for example, when the calculated estimated transmission rate is “5.0 Mbps” and the Max value related to the transmission rate stored in the transmission rate information storage unit 153 is “3.4 Mbps”, the transmission rate calculation unit 152 Determines that the calculated estimated transmission rate is larger than the Max value relating to the read estimated transmission rate. When the transmission rate calculation unit 152 determines in step S108 that the calculated estimated transmission rate is larger than the Max value related to the read estimated transmission rate, the transmission rate calculation unit 152 transmits the transmission rate information storage unit in step S109. The Max value of the transmission rate stored in 153 is updated to the calculated estimated transmission rate. On the other hand, when the transmission rate calculation unit 152 determines in step S108 that the calculated estimated transmission rate is equal to or less than the Max value regarding the read estimated transmission rate, the transmission rate calculation unit 152 skips the process of step S109. . Thereby, the maximum value of the transmission rate stored in the transmission rate information storage unit 153 is not updated and is maintained as it is.

  In step S110, the transmission rate calculation unit 152 reads the Min value related to the estimated transmission rate stored in the transmission rate information storage unit 153 (the Min value related to the past estimated transmission rate predicted by the mobile communication terminal 101 so far). Then, it is determined whether or not the calculated estimated transmission rate is smaller than the Min value regarding the read estimated transmission rate. For example, when the calculated estimated transmission rate is “1.2 Mbps” and the Min value related to the estimated transmission rate stored in the transmission rate information storage unit 153 is “100 kbps”, the transmission rate calculating unit 152 calculates The determined estimated transmission rate is determined to be larger than the Min value related to the read estimated transmission rate. On the other hand, for example, when the calculated estimated transmission rate is “90 kbps” and the Min value related to the estimated transmission rate stored in the transmission rate information storage unit 153 is “100 kbps”, the transmission rate calculation unit 152 calculates The determined estimated transmission rate is determined to be smaller than the Min value related to the read estimated transmission rate. When the transmission rate calculation unit 152 determines in step S110 that the calculated estimated transmission rate is smaller than the Min value related to the estimated transmission rate that has been read, the transmission rate calculation unit 152 performs the transmission rate information storage unit in step S111. The Min value of the transmission rate stored in 153 is updated to the calculated estimated transmission rate. On the other hand, when the transmission rate calculation unit 152 determines in step S110 that the calculated estimated transmission rate is equal to or greater than the Min value related to the read estimated transmission rate, the transmission rate calculation unit 152 skips the process of step S111. Thereby, the Min value of the transmission rate stored in the transmission rate information storage unit 153 is not updated and is maintained as it is.

  As described above, the transmission rate information storage unit 153 updates the Min value and the Max value related to the current estimated transmission rate and the estimated transmission rate according to the control of the transmission rate calculation unit 152 by the processing of Steps S102 to S111. For example, when the calculated estimated transmission rate is “1.5 Mbps” and the Min value and the Max value related to the estimated MCS level are not changed, only the current estimated transmission rate stored in the transmission rate information storage unit 153 is “ It is updated to “1.5 Mbps”.

  In step S113, the control unit 120 reads the current estimated transmission rate stored in the transmission rate information storage unit 153, the Min value and the Max value related to the estimated transmission rate, and the read current estimated transmission rate and estimated transmission rate. The display unit 123 updates the display using the Min value and the Max value. Thereby, while the mobile communication terminal 101 is waiting with the base station, the current transmission rate (currently predicted transmission rate) displayed on the display unit 123 and the Min value and the Max value related to the estimated transmission rate are transmitted rate information. The current estimated transmission rate stored in the storage unit 153 and the Min value and the Max value related to the estimated transmission rate are updated every predetermined cycle (a paging cycle or an integer multiple of the paging cycle). FIG. 16 shows the current estimated transmission rate displayed on the display unit 123, and the Min value and the Max value related to the estimated transmission rate. In the case of FIG. 16, “1.2 Mbps” is displayed as the current estimated transmission rate, “100 kbps” is displayed as the Min value related to the estimated transmission rate, and “3.4 Mbps” is displayed as the Max value related to the transmission rate. In step S113, the control unit 120 determines whether to start data communication with the base station on which the mobile communication terminal 101 is waiting. When the control unit 120 determines in step S113 that the mobile communication terminal 101 does not start data communication with the base station on which the mobile communication terminal 101 is waiting, the process returns to step S102, and the mobile communication terminal 101 continues the standby mode, The current estimated transmission rate and the Min value and the Max value related to the estimated transmission rate are appropriately updated. Note that the current estimated transmission rate stored in the transmission rate information storage unit 153 and the Min value and the Max value related to the estimated transmission rate are initialized at a constant cycle (for example, a cycle of 30 minutes). The current estimated transmission rate stored in the transmission rate information storage unit 153 and the period at which the Min value and the Max value related to the estimated transmission rate are initialized are arbitrarily designated by the user, and the designated period is designated by the mobile communication terminal 101. May be set as the initialization period.

  On the other hand, when it is determined in step S113 that the control unit 120 starts data communication with the base station on which the mobile communication terminal 101 is waiting, the control unit 120 performs the wireless unit 112, the received signal processing unit in step S114 of FIG. 113, the SINR measurement unit 125, the CQI information generation unit 126, and the transmission signal processing unit 130 are controlled and negotiated with the base station to determine the MCS used for communication. Specifically, the mobile communication terminal 101 transmits CQI information to the base station, and the base station transmits user information and transmission format information of the channel of the individual information and band information to be used to the mobile communication terminal 101. The mobile communication terminal 101 receives the individual information channel from the base station based on the information put on the control channel via the radio unit 112 and the received signal processing unit 113, and the control unit 120 Acquires this dedicated information channel and recognizes the MCS used for communication. The control unit 120 of the mobile communication terminal 101 controls the radio unit 112, the reception signal processing unit 113, and the transmission signal processing unit 130, and starts data communication using the MCS determined by negotiation with the base station.

  In step S115, the transmission rate calculation unit 152 sets the MCS (MCS level) determined between the mobile communication terminal 101 and the base station according to the control of the control unit 120, and the radio resource amount allocated by the base station. Based on this, a transmission rate Er in data communication is calculated. In step S116, the transmission rate calculation unit 152, under the control of the control unit 120, calculates the calculated transmission rate Er during data communication and the current estimated transmission rate Er stored in the transmission rate information storage unit 153 (display unit 123). It is determined whether or not the current estimated transmission rate displayed by (1) is different.

  When the transmission rate calculation unit 152 determines in step S116 that the calculated transmission rate Er at the time of data communication is different from the current estimated transmission rate Er stored in the transmission rate information storage unit 153, the transmission rate calculation unit Reference numeral 152 denotes an estimated transmission rate (estimated transmission displayed by the display unit 123) stored in the transmission rate information storage unit 153 based on the calculated transmission rate Er during data communication in accordance with the control of the control unit 120 in step S117. Change (update) the rate. For example, when the calculated transmission rate Er at the time of data communication is “1.5 Mbps” and the estimated transmission rate stored in the transmission rate information storage unit 153 is “1.2 Mbps”, the transmission rate information is stored. The current estimated transmission rate stored in the unit 153 is updated to “1.5 Mbps”. On the other hand, when the transmission rate calculation unit 152 determines in step S116 that the calculated transmission rate Er during data communication and the estimated transmission rate Er stored in the transmission rate information storage unit 153 are the same, step S117 This process is skipped.

  In step S118, the transmission rate calculation unit 152 reads the Max value related to the estimated transmission rate stored in the transmission rate information storage unit 153, and the calculated transmission rate Er during data communication relates to the read estimated transmission rate. It is determined whether or not it is larger than the Max value. For example, when the calculated transmission rate at the time of data communication is “1.5 Mbps”, the transmission rate calculation is performed when the Max value related to the estimated transmission rate stored in the transmission rate information storage unit 153 is “3.4 Mbps”. The unit 152 determines that the calculated transmission rate Er at the time of data communication is smaller than the Max value related to the read estimated transmission rate. On the other hand, for example, when the calculated transmission rate Er at the time of data communication is “4.0 Mbps”, the Max value regarding the estimated transmission rate stored in the transmission rate information storage unit 153 is “3.4 Mbps”. The transmission rate calculation unit 152 determines that the calculated transmission rate Er at the time of data communication is larger than the Max value regarding the read estimated transmission rate. When the transmission rate calculation unit 152 determines in step S118 that the calculated transmission rate Er at the time of data communication is larger than the Max value regarding the read estimated transmission rate Er, the transmission rate calculation unit 152 determines in step S119, The maximum value of the estimated transmission rate Er stored in the transmission rate information storage unit 153 is updated to the calculated transmission rate Er at the time of data communication. On the other hand, when the transmission rate calculation unit 152 determines in step S118 that the calculated transmission rate Er during data communication is equal to or less than the Max value related to the read estimated transmission rate, the transmission rate calculation unit 152 Skip processing. As a result, the Max value of the estimated transmission rate stored in the transmission rate storage unit 152 is not updated and is maintained as it is.

  In step S120, the transmission rate calculation unit 152 reads the Min value related to the estimated transmission rate stored in the transmission rate information storage unit 153, and the calculated transmission rate Er at the time of data communication is the read estimated transmission rate Er. It is determined whether or not it is smaller than the Min value. For example, when the calculated transmission rate Er at the time of data communication is “150 kbps” and the Min value related to the estimated transmission rate Er stored in the transmission rate information storage unit 153 is “100 kbps”, the transmission rate calculation unit 152 determines that the calculated transmission rate Er during data communication is larger than the Min value related to the read estimated transmission rate Er. On the other hand, for example, when the calculated transmission rate Er during data communication is “90 kbps”, when the Min value related to the estimated transmission rate Er stored in the transmission rate information storage unit 153 is “100 kbps”, the transmission rate The calculation unit 152 determines that the calculated transmission rate Er at the time of data communication is smaller than the Min value related to the read estimated transmission rate Er. When the transmission rate calculation unit 152 determines in step S120 that the calculated transmission rate Er at the time of data communication is smaller than the Min value related to the read estimated transmission rate Er, the transmission rate calculation unit 152 determines in step S121. The Min value of the transmission rate Er stored in the transmission rate information storage unit 153 is updated to the calculated transmission rate Er at the time of data communication. On the other hand, when the transmission rate calculation unit 152 determines in step S120 that the calculated transmission rate Er during data communication is equal to or greater than the Min value related to the read estimated transmission rate Er, the transmission rate calculation unit 152 performs the process of step S121. To skip. Thereby, the Min value of the estimated transmission rate Er stored in the transmission rate information storage unit 153 is not updated and is maintained as it is.

  In step S122, the control unit 120 reads the current estimated transmission rate Er stored in the transmission rate information storage unit 153, the Min value and the Max value related to the estimated transmission rate Er, and the read current estimated transmission rate Er. The display on the display unit 123 is updated using the Min value and the Max value related to the estimated transmission rate Er. Thereby, when the mobile communication terminal 101 starts data communication with the base station, the current estimated transmission rate Er displayed on the display unit 123 and the Min value and the Max value related to the estimated transmission rate Er are stored in the transmission rate information storage. The current estimated transmission rate Er stored in the unit 153 and the Min value and the Max value related to the estimated transmission rate Er are updated.

  In step S123, the control unit 120 determines whether to end data communication with the base station on which the mobile communication terminal 101 is waiting, and performs data communication with the base station on which the mobile communication terminal 101 is waiting. The mobile communication terminal 101 waits until it is determined to end, and performs data communication with the base station. When the control unit 120 determines in step S123 that the data communication with the base station on which the mobile communication terminal 101 is waiting is terminated, the process returns to step S101, and the control unit 120 includes the radio unit 112 and the received signal processing unit. 113 is started, the standby mode is started for any of the base stations belonging to the mobile communication system, and then the processing after step S102 is started.

  By the way, in the case of the transmission rate display control processing described using FIG. 14 and FIG. 15, the mobile communication terminal 101 determines the estimated MCS level related to the frequency band used by the base station belonging to the mobile communication system, and the congestion degree Tr. Based on the above, the estimated estimated transmission rate is calculated and the calculated estimated transmission rate Er is displayed. However, the present invention is not limited to such a case. That is, the mobile communication terminal 101 detects the MCS determined by the other mobile communication terminal 101 with the base station during the data communication with the base station on which the mobile communication terminal 101 is waiting or the negotiation at the time of data communication, and based on the detection result MCS histograms (hist; frequency distribution) for all mobile communication terminals 101 during data communication with the base station or during data communication negotiations are created, and the created MCS histograms and estimated MCS levels at the terminal itself And the estimated transmission rate Er based on the estimated MCS level and the congestion degree Tr in the own terminal may be corrected. Thus, instead of simply estimating and displaying the transmission rate by estimating the amount of radio resources allocated to the terminal based on broadcast information or downlink resource allocation information from the base station, other mobile communication terminals 101 Based on the MCS, the reception quality at the mobile communication terminal 101 within the coverage area of the base station is grasped, and the possibility of selection of the own terminal for the base station scheduler is determined by comparing with the estimated MCS level at the own terminal. In addition, it is possible to predict and display the transmission rate in consideration of the frequency resource allocation probability based on the scheduling of the base station. Hereinafter, transmission rate display control processing using this method will be described.

  The transmission rate display control process in the mobile communication terminal 101 in FIG. 13 will be described with reference to the flowcharts in FIGS. 17 and 18. 17 and 18, it is assumed that the mobile communication terminal 101 has started a standby mode, and the mobile communication terminal 101 is one of those belonging to a mobile communication system (such as an OFDMA mobile communication system). Waiting for a base station. Also, the processes in FIGS. 17 and 18 are basically the same as the processes in FIGS. 14 and 15, and the description thereof will be repeated, and will be omitted as appropriate.

  In step S154, the mobile communication terminal 101 receives a broadcast channel constantly transmitted from the base station. The allocation information acquisition unit 151 is another mobile communication terminal that is negotiating during data communication or data communication with the base station on which the mobile communication terminal 101 is waiting, from the broadcast information or downlink resource allocation information from the base station. Detect the MCS level.

  Thereafter, in step S158, the transmission rate calculation unit 152 determines the estimated transmission rate Er that is estimated based on the estimated MCS level related to the frequency band used by the base station belonging to the mobile communication system and the congestion degree Tr. A reference estimated transmission rate Er0 is calculated. In step S159, the transmission rate calculation unit 152 determines the MCS level related to the other mobile communication terminal 101 (other mobile communication terminals that are in communication with the base station on which the mobile communication terminal 101 is awaiting or are negotiating during data communication). MCS level) histogram (frequency distribution). FIGS. 19A and 19B show MCS level histograms for other mobile communication terminals. In step S160, the transmission rate calculation unit 152 calculates the median value CV of the histogram of the MCS level for the other mobile communication terminals 101, as shown in FIG. 19 (A) or (B). Note that the transmission rate calculation unit 152 may calculate the average value of the MCS level histograms related to the other mobile communication terminals 101 instead of the median value of the MCS level histograms related to the other mobile communication terminals 101. . Next, in step S161, the transmission rate calculation unit 152 determines the difference D (= estimated MCS level of the own terminal) between the median value CV of the histogram of the MCS level for the other mobile communication terminals 101 and the estimated MCS level of the own terminal. Xk-CV) is calculated. Here, “k” is a constant.

  In step S162, the transmission rate calculation unit 152 calculates a correction coefficient w for correcting the reference estimated transmission rate Er0 based on the calculated difference D. Specifically, the transmission rate calculation unit 152 calculates the correction coefficient w as one example as follows. That is, when the calculated difference D is 0, the transmission rate calculation unit 152 increases or decreases the frequency resource allocation probability based on the scheduling of the base station with respect to the reference value (reference value related to the allocation probability). Therefore, the correction coefficient w for correcting the reference estimated transmission rate Er0 is calculated (set) as 1, and if the difference D is greater than 0, scheduling of the base station Therefore, the correction coefficient w for correcting the reference estimated transmission rate Er0 is set to α (in accordance with the value of the difference D). 1 <α ≦ 2) is calculated (set), and if the difference D is smaller than 0, frequency resource allocation by base station scheduling is performed. Since it is considered that the guess probability is increased with respect to the reference value (reference value related to the allocation probability), a correction coefficient w for correcting the reference estimated transmission rate Er0 is set to β (0 ≦ β < 1) is calculated (set). Here, FIG. 19A shows a case where the difference D is smaller than 0, and FIG. 19B shows a case where the difference D is larger than 0.

  Of course, in order to simplify the calculation process of the correction coefficient w, the transmission rate calculation unit 152 sets the correction coefficient w to 1 when the difference D is 0, and the difference D is larger than 0. Alternatively, the correction coefficient w may be uniformly set to 1.5, and when the difference D is smaller than 0, the correction coefficient w may be uniformly set to 0.5.

  In step S163, the transmission rate calculation unit 152 calculates the estimated estimated transmission rate Er using the reference estimated transmission rate Er0 and the correction coefficient w. Specifically, the transmission rate calculation unit 152 performs correction by multiplying the reference estimated transmission rate Er0 by the correction coefficient w, and calculates the estimated estimated transmission rate Er. Also, the transmission rate calculation unit 152 updates the current estimated transmission rate Er stored in the transmission rate information storage unit 153 based on the calculated estimated transmission rate Er (predicted estimated transmission rate). The transmission rate information storage unit 153 stores the current estimated transmission rate Er according to the control of the transmission rate calculation unit 152. Thereby, the mobile communication terminal 101 can display the predicted throughput in consideration of the frequency resource allocation probability based on the scheduling of the base station in addition to the congestion degree Tr of the base station on which the mobile communication terminal 101 is waiting. become.

  Thereafter, the process proceeds to step S164, and the processes after step S164 are performed.

  Thus, the mobile communication terminal 101 according to the second embodiment of the present invention transmits and receives radio signals between the mobile communication terminal 101 and a base station belonging to the mobile communication system, and A radio signal transmitted / received to / from a base station belonging to a mobile communication system is processed, and a plurality of signals are determined in advance according to a transmission path state between the mobile communication terminal 101 and a base station belonging to the mobile communication system. The mobile communication terminal 101 and the base station belonging to the mobile communication system are determined as any one of the MCSs, which is a combination of the modulation scheme and the error correction coding rate, using the determined MCS. Controls communication with a base station belonging to a mobile communication system, detects reception quality of a radio signal from a base station belonging to a mobile communication system on which the mobile communication terminal 101 is awaited, and For each resource block included in a frequency band used by a base station belonging to a mobile station, channel state information including MCS level of MCS based on detected reception quality among a plurality of MCSs is generated, and mobile communication Of the broadcast information or downlink resource allocation information from the base station belonging to the system, the frequency bandwidth used by the base station belonging to the mobile communication system and the data communication with the base station on which the mobile communication terminal 101 is waiting or The number of other mobile communication terminals 101 in negotiation during data communication is detected, and the detected frequency bandwidth and the base station on which the mobile communication terminal 101 is waiting are in data communication or during data communication negotiation. Based on the number of other mobile communication terminals 101, the degree of congestion related to base stations belonging to the mobile communication system is calculated, and mobile communication When the terminal 101 is waiting for a base station belonging to the mobile communication system, the mobile communication terminal 101 is connected to the base station belonging to the mobile communication system based on the generated channel state information for each resource block. An estimated MCS level at the mobile communication terminal 101 in data communication is calculated, and the mobile communication terminal 101 belongs to the mobile communication system based on the calculated estimated MCS level and the calculated degree of congestion. It is possible to calculate an estimated transmission rate when performing data communication with the base station, and display the calculated estimated transmission rate.

  Thereby, the mobile communication terminal 101 according to the second embodiment of the present invention performs CQI measurement even during standby, and calculates an estimated transmission rate based on the radio resource amount estimated as CQI (MCS level). It is possible to display the communication quality (reception quality) suitably in real time. Then, the user can recognize where the transmission path condition is actually good, prompt the user to perform wireless communication in a place with good reception quality, and reduce the power consumption of the mobile communication terminal 101. And sector throughput can be improved. Moreover, the mobile communication system can perform data transmission using MCS with good transmission efficiency, and can improve the frequency utilization efficiency.

[Third Embodiment]
The mobile communication terminal 101 according to the first embodiment and the second embodiment can suitably display the reception quality (MCS level or transmission rate) by performing CQI measurement even during standby. Thereby, the mobile communication terminal 101 according to the first embodiment and the second embodiment performs CQI measurement even during standby, suitably displays the reception quality (MCS level or transmission rate), and displays the reception quality to the user. Can be encouraged to perform wireless communication in a good location, and the power consumption of the mobile communication terminal 101 can be reduced and the sector throughput can be improved. However, for example, when the user desires to download (DL) data to the mobile communication terminal 101 via the base station, the reception quality is improved when the mobile communication terminal 101 receives an instruction to start downloading. If the download is started immediately regardless of the time, it takes time to download the data, and the power consumption at the time of downloading the data cannot be reduced.

  Therefore, the mobile communication terminal 101 according to the third embodiment is a mode in which download is started regardless of reception quality (MCS level or transmission rate) when the mobile communication terminal 101 receives an instruction to start downloading (normal) Mode) or a mode in which downloading is started in principle when the reception quality is better than the reference value (eco mode). For example, a case where CQI measurement is performed and the MCS level as the reception quality is displayed even when the mobile communication terminal 101 is on standby will be specifically described. FIG. 20 shows modes that the mobile communication terminal 101 can select for download. When the mobile communication terminal 101 is set to a mode (normal mode) in which downloading is started regardless of reception quality when receiving an instruction to start downloading, as shown in FIG. When the body communication terminal 101 receives a download start instruction, the download starts immediately regardless of the reception quality. That is, in the case of FIG. 20, the CQI Index at the time when the mobile communication terminal 101 starts to download data from the base station after receiving the data download start instruction is “3”, which corresponds to the CQI Index. The MCS level is “MCS level 3”. While the mobile communication terminal 101 is downloading data from the base station, the CQI index changes from “3” to “5”, and the MCS level corresponding to the CQI index is “ Transition from "MCS level 3" to "MCS level 5". If only the result of the transition of the MCS level is seen, the mobile communication terminal 101 considers the time required for data download and the power consumption at the time of data download, after the MCS level transitions to “MCS level 5”. It seems that the data download should have started. However, since the mode set by the mobile communication terminal 101 is the normal mode, the mobile communication terminal 101 assumes that the reception quality is “MCS level 3” when receiving an instruction to start downloading. Will start downloading immediately.

  On the other hand, when the mobile communication terminal 101 sets a mode (eco-mode 1 or eco-mode 2) that starts downloading in principle when the reception quality is better than the reference value, as shown in FIG. Even if the mobile communication terminal 101 receives an instruction to start downloading, the mobile communication terminal 101 does not start downloading when the reception quality when receiving the instruction is not better than the reference value, and the reception quality is better than the reference value. When the download starts. In the case of FIG. 20, the CQI Index at the time when the mobile communication terminal 101 receives an instruction to start downloading data is “3”, and the MCS level corresponding to the CQI Index is “MCS level 3”. While the terminal 101 is downloading data from the base station, the CQI Index transitions from “3” to “5”, “9”, and then “12”, and the MCS level corresponding to the CQI Index is “MCS level 3”. To “MCS level 5”, “MCS level 9”, and then “MCS level 12”. Since the mode set by the mobile communication terminal 101 is the eco mode 1, the mobile communication terminal 101 has a reference quality (in the case of FIG. 20, the reference value is MCS when receiving a download start instruction). If it is not better than (level 10), the download is not started, and the download is started when the reception quality is better than the reference value. In the eco mode 1 set by the mobile communication terminal 101, the mobile communication terminal 101 starts downloading only when the reception quality is better than the reference value without intentionally setting a data download completion time limit. Mode. Therefore, even if the mobile communication terminal 101 receives an instruction to start downloading data, the data download is not started unless the reception quality is better than the reference value.

  On the other hand, in the eco mode 2 set by the mobile communication terminal 101, the mobile communication terminal 101 sets a data download completion time limit and starts downloading in principle when the reception quality is better than the reference value. However, if the data download does not start until the data download completion time is approaching, even if the reception quality is not better than the reference value, the data download is completed within the data download completion time limit. Start downloading. Since the mode set by the mobile communication terminal 101 is the eco mode 2, the mobile communication terminal 101 has a reference quality (in the case of FIG. 20, the reference value is MCS when receiving a download start instruction). Download is not started when it is not better (level 10), and download is generally started when reception quality is better than the reference value, but download of data is completed within the download completion time limit Data download is started.

  The download mode setting process in the mobile communication terminal 101 of FIG. 8 or 13 will be described with reference to the flowchart of FIG.

  In step S <b> 201, the control unit 120 determines whether or not an instruction to start the data download mode setting process is received by the operation of the operation unit 122 by the user, and the data download mode setting process is performed. Wait until it is determined that an instruction to start is accepted. If the control unit 120 determines in step S201 that an instruction to start the data download mode setting process has been received, the control unit 120 receives a selection related to the data download mode in step S202. In the data download mode, when the mobile communication terminal 101 receives an instruction to start downloading, the mode starts downloading regardless of the reception quality (normal mode), and the data download completion time limit is not provided. Eco-mode 1 that starts downloading only when the quality is better than the reference value. Downloading data while starting the download when the reception quality is better than the reference value by setting a data download completion time limit. There is an eco mode 2 in which data download is started so that data download is completed within the data download completion time limit when data download is not started until the completion time is near. The user can arbitrarily select any one of the three download modes. In step S203, the control unit 120 sets the data download mode to the download mode in which the selection has been accepted, according to the selection related to the data download mode. In step S204, the control unit 120 causes the storage unit 124 to store setting information regarding the download mode. In step S <b> 205, the control unit 120 stores setting information regarding the download mode according to the control of the control unit 120.

  Next, the data download control process in the mobile communication terminal 101 of FIG. 8 will be described with reference to the flowchart of FIG. In FIG. 22, it is assumed that the mobile communication terminal 101 has started a standby mode, and the mobile communication terminal 101 is one of base stations belonging to a mobile communication system (such as an OFDMA mobile communication system). And waiting. In addition, the mobile communication terminal 101 basically executes the MCS level display control process described with reference to FIG. 9 in parallel with the data download control process.

  In step S251, the control unit 120 controls the radio unit 112 and the received signal processing unit 113 to start a standby mode for any base station belonging to the mobile communication system. In step S <b> 252, the control unit 120 determines whether or not an instruction to start downloading data is received when the operation unit 122 is operated by the user, and until an instruction to start downloading data is received. stand by. When the mobile communication terminal 101 waits until receiving an instruction to start downloading data, it performs the MCS level display control processing described with reference to FIG. 9 in parallel.

  If the control unit 120 determines in step S252 that an instruction to start downloading data has been received, the control unit 120 reads the download setting information stored in the storage unit 124 in step S253 and reads the downloaded download. Based on the setting information, it is determined whether or not the set data download mode is the normal mode. If the control unit 120 determines in step S253 that the set data download mode is the normal mode, the process proceeds to step S258 so that the mobile communication terminal 101 can immediately start downloading data. . In step S258, the control unit 120 controls the radio unit 112, the reception signal processing unit 113, the SINR measurement unit 125, the CQI information generation unit 126, and the transmission signal processing unit 130, and negotiates with the base station. Determine the MCS to be used for communication. Note that the MCS determination method is the same as the determination method in step S10 of FIG. In step S259, the control unit 120 of the mobile communication terminal 101 controls the radio unit 112, the reception signal processing unit 113, and the transmission signal processing unit 130, and uses the MCS determined by negotiation with the base station from the base station. Download data for. Thereafter, when the mobile communication terminal 101 finishes downloading data from the base station, the process proceeds to step S260. In step S260, the control unit 120 controls the radio unit 112 and the received signal processing unit 113 to return to a standby mode for any base station belonging to the mobile communication system.

  On the other hand, when the control unit 120 determines in step S253 that the set download mode of the data is not the normal mode, the control unit 120 sets the set data based on the read download setting information in step S254. It is determined whether or not the download mode is the eco mode 1 of the eco modes. When the control unit 120 determines in step S254 that the data download mode is the eco mode 1, the control unit 120 uses the base station belonging to the mobile communication system to which the mobile communication terminal 101 is connected in step S255. The radio unit 112 and the received signal processing unit 113 are controlled so that SINRs in all resource blocks included in the frequency band can be measured. The SINR measurement unit 125 is included in a frequency band used by a base station belonging to a mobile communication system to which the mobile communication terminal 101 is connected, with a paging cycle or an integer multiple of a paging cycle (such as 2 or 3). Each RB (resource block) measures the radio channel quality (SINR) related to the received signal from the received signal processing unit 113 and outputs the measurement result of each RB to the CQI information generating unit 126. The CQI information generation unit 126 determines a receivable MCS based on the measurement result by the SINR measurement unit 125 in each RB included in the frequency band used by the base station belonging to the mobile communication system, and determines the determined transmission format Based on (combination of modulation scheme and error correction coding rate), channel state information (CQI information) is generated. The CQI information for each RB includes a CQI Index indicating a combination (MCS) of a modulation scheme and an error correction coding rate, and an MCS level corresponding to the CQI Index. CQI information generation section 126 outputs CQI information for each RB to CQI information control section 127.

  In step S256, the CQI information control unit 127 acquires CQI information for each RB included in the frequency band used by the base station belonging to the mobile communication system to which the mobile communication terminal 101 is connected, and acquires each RB that has been acquired. Based on the CQI information for each, an estimated MCS level relating to a frequency band used by a base station belonging to the mobile communication system is calculated. Note that the calculation method of the estimated MCS level regarding the frequency band used by the base station belonging to the mobile communication system in step S256 is basically the same as the calculation method in step S3 of FIG. 9, and the description thereof will be repeated. I will omit it. Also, the CQI information control unit 127 updates the current estimated MCS level stored in the CQI information storage unit 128 based on the calculated estimated MCS level. The CQI information storage unit 128 stores the current estimated MCS level according to the control of the CQI information control unit 127. Further, at this time, similarly to the processing of steps S3 to S7 of FIG. Update.

  In step S257, the CQI information control unit 127 determines whether or not the calculated MCS level is greater than or equal to a preset reference value. This reference value is a reference value related to reception quality for determining whether or not to start downloading data, and is set in advance as a fixed value such as “MCS level 10”, for example. Of course, the reference value may be set to an arbitrary value by the user, or the value may be changed as appropriate. Further, this reference value may be set to an MCS level that is higher in the N stage level than the Min value related to the estimated MCS level, or set to an MCS level that is lower than the Max value related to the MCS level. You may do it. For example, when the Min value regarding the estimated MCS level is “MCS level 2”, “MCS level 8”, which is higher than “MCS level 2” by 6 levels (N levels = 6 levels), is set as the reference value. The The value of “N” may be set to an arbitrary value by the user. Furthermore, the mobile communication terminal 101 receives, for example, reception quality for determining whether to start data download based on the current estimated MCS level at the time when the instruction to start data download is accepted. A reference value for the value may be set. Specifically, the mobile communication terminal 101 sets, for example, an MCS level that is higher than the current estimated MCS level at the time when an instruction to start downloading data is received as the reference value. It may be. For example, when the value of N is “5” and the current estimated MCS level is “MCS level 13”, the maximum level “MCS level 15” is set as the reference value.

  If the CQI information control unit 127 determines in step S257 that the calculated MCS level is not equal to or higher than a preset reference value, the process returns to step S255, and the processes after step S255 are repeatedly executed. Thereby, the mobile communication terminal 101 can prevent the download from starting when the reception quality when receiving the instruction to start the download is not better than the reference value. On the other hand, when the CQI information control unit 127 determines in step S257 that the calculated MCS level is equal to or higher than a preset reference value, the process proceeds to step S258, and the mobile communication terminal is processed by the processes after step S258. 101 negotiates with the base station, determines an MCS to be used for communication, and starts downloading data from the base station using the MCS determined in the negotiation with the base station.

  On the other hand, when the control unit 120 determines in step S254 that the data download mode is not the eco mode 1, the control unit 120 recognizes that the data download mode is the eco mode 2, and the mobile communication terminal 101 Steps S261 through S263 are executed. Note that the processing in steps S261 to S263 is the same as the processing in steps S255 to S257 described above. If the CQI information control unit 127 determines in step S263 that the calculated MCS level is greater than or equal to a preset reference value, the process proceeds to step S258. If the CQI information control unit 127 determines in step S263 that the calculated MCS level is not equal to or higher than a preset reference value, the CQI information control unit 127 is a predetermined time before the download completion time in step S264. It is determined whether or not. This download completion time may be input by the user at the time of the data download start instruction, or set in advance in a uniform manner, such as how many hours after the download start instruction time. You may make it do. The predetermined time is, for example, 30 minutes.

  If the CQI information control unit 127 determines in step S264 that it is not a predetermined time before the download completion time, the process returns to step S261, and the processes after step S261 are repeatedly executed. On the other hand, when the CQI information control unit 127 determines in step S264 that it is a predetermined time before the download completion time, the process proceeds to step S258, and the mobile communication terminal 101 is processed by the base station by the process after step S258. And MCS to be used for communication is determined, and downloading of data from the base station is forcibly started using the MCS determined by negotiation with the base station regardless of the reception quality.

  Next, the data download control process in the mobile communication terminal 101 of FIG. 13 will be described with reference to the flowchart of FIG. In FIG. 23, it is assumed that the mobile communication terminal 101 has started the standby mode, and the mobile communication terminal 101 is one of the base stations belonging to the mobile communication system (such as the OFDMA mobile communication system). And waiting. In addition, the mobile communication terminal 101 basically executes the MCS level display control process described with reference to FIGS. 14 to 15 in parallel with the data download control process. The processes in steps S281 through S284, steps S286 through S287, steps S293 through S295, and steps S297 through S298 in FIG. 23 are the same as the processes in steps S251 through S256, steps S258 through S260, and steps S261 through S262 in FIG. This is the same, and the description thereof will be repeated, and will be omitted. Also, the processes in steps S285, S288 to S289, S296, and S299 to S300 in FIG. 23 are the same as the processes in steps S102 to S103 and steps S106 to S107 in FIG. It will be omitted.

  If the control unit 120 determines in step S284 that the data download mode is the eco mode 1, the process proceeds to step S285, and the processes after step S285 are executed. Then, in step S290, the transmission rate calculation unit 152, based on the content capacity of the data to be downloaded and the estimated transmission rate Er that is predicted, the estimated download time required when data is downloaded (= content capacity / predicted). The estimated transmission rate Er) is calculated. For example, when the content capacity of data to be downloaded is 240 [Mbit] and the estimated transmission rate Er predicted is 1.2 [Mbps], the estimated download time is 240 / 1.2 = 200 [s]. . The content capacity is a known value in advance in the mobile communication terminal 101.

  In step S291, the control unit 120 sets a reference value related to the estimated download time. Below, the setting method of the reference value regarding concrete estimated download time is demonstrated. First, the first reference value setting method will be described. In this case, the control unit 120 estimates the coverage area of the radio wave from the base station based on the measurement result regarding the received signal strength from the RSSI measurement section 121, and according to the coverage area of the base station. Set a reference value for estimated download time. The received signal strength increases in proportion to the transmission power of the base station. The cover area will be narrow. When the coverage area of the base station becomes wide (when the base station is a macro cell), the CQI measured by the mobile communication terminal 101 does not change suddenly and is estimated to be stable. On the other hand, when the coverage area of the base station becomes narrow (when the base station is a micro cell), the CQI measured by the mobile communication terminal 101 is likely to change suddenly. Therefore, the mobile communication terminal 101 changes the reference value for the estimated download time according to the cover area size of the base station, and increases the reference value for the estimated download time when the cover area size of the base station is large. When the cover area size of the base station is small, the reference value for the estimated download time is reduced. For example, 20 [s] and 120 [s] are prepared in advance as reference values related to the estimated download time, and the mobile communication terminal 101 estimates when the base station cover area size is larger than a predetermined threshold. If the reference value for the download time is set to 120 [s] and the cover area size of the base station is equal to or smaller than a predetermined threshold, the reference value for the estimated download time is set to 20 [s].

  FIG. 24 is an explanatory diagram illustrating a setting method for setting a reference value related to the estimated download time according to the cover area size of the base station. As shown in FIG. 24, for example, when the user is moving by subway with the mobile communication terminal 101, the user should connect to a base station (microcell) having a small cover area size while the subway stops at the stop station. However, it is out of range while the subway is running between the stations. At this time, since the cover area size of the base station is equal to or smaller than a predetermined threshold value, the mobile communication terminal 101 sets the reference value for the estimated download time to 20 [s], for example. On the other hand, when the user gets off the subway and goes to the ground, it is possible to connect to a base station (macrocell) having a large cover area size, and the cover area size of the base station is larger than a predetermined threshold value. Accordingly, the mobile communication terminal 101 sets the reference value related to the estimated download time to 120 [s], for example.

  Of course, the mobile communication terminal 101 may set the reference value for the estimated download time in multiple stages according to the cover area size of the base station. That is, the mobile communication terminal 101 sets a plurality of predetermined threshold values related to the coverage area size of the base station, and sets the estimated download time according to the coverage area size of the base station divided by the plurality of threshold values. Set in multiple stages. Thereby, the mobile communication terminal 101 can set a reference value related to the estimated download time that is appropriate in high definition in accordance with the change in the transmission rate and the CQI.

  Next, the second reference value setting method will be described. In this case, the control unit 120 controls the radio unit 112 and the received signal processing unit 113 to determine whether a handover (HO) or a cell search (base station search) has occurred in parallel with the data download control process. The number of handovers and cell searches is counted up. In step S291, the control unit 120 sets a reference value related to the estimated download time according to the frequency (number of times) of handover (HO) and cell search (base station search). Note that “handover” means switching of base stations, and “base station search” is a so-called cell search process, which is a cell (base station) with the smallest propagation loss to which the mobile communication terminal 101 should be connected. ) Frequency, reception timing, and cell number (ID) detection processing.

  When the mobile communication terminal 101 owned by the user is moving at a low speed, handover and cell search do not occur frequently, and the CQI measured at the mobile communication terminal 101 does not change suddenly and is stable. It is guessed. On the other hand, when the mobile communication terminal 101 owned by the user is moving at high speed, handover and cell search frequently occur, and the CQI measured by the mobile communication terminal 101 is likely to change suddenly. Therefore, the mobile communication terminal 101 changes the reference value related to the estimated download time according to the frequency of handover and cell search, and when the number of times of handover and cell search per unit time is large, the estimated download time The reference value for the estimated download time is reduced when the reference value for the estimated download time is small. For example, 30 [s] and 180 [s] are prepared in advance as reference values for the estimated download time, and the mobile communication terminal 101 determines that the number of times per unit time of handover or cell search is from a predetermined threshold Is set to 180 [s], and when the number of handovers or cell searches per unit time is equal to or less than a predetermined threshold, the reference value for the estimated download time is set to 30 [s]. s].

  FIG. 25 is an explanatory diagram illustrating a setting method for setting a reference value related to the estimated download time in accordance with the number of handovers per unit time. As shown in FIG. 25, for example, when the user is moving by train with the mobile communication terminal 101, handover frequently occurs, and the number of handovers per unit time is below a predetermined threshold value. For this reason, the mobile communication terminal 101 sets a reference value related to the estimated download time to 30 [s], for example. On the other hand, when the user is at home, for example, handover does not occur frequently, and the number of handovers per unit time is greater than a predetermined threshold value. For example, the reference value for the download time is set to 180 [s].

  Of course, the mobile communication terminal 101 may set the reference value for the estimated download time in multiple stages according to the number of handovers or cell searches.

  The control unit 120 outputs a reference value related to the set estimated download time to the transmission rate calculation unit 152. In step S291, the transmission rate calculation unit 152 determines whether or not the calculated estimated download time is equal to or greater than a preset reference value for the estimated download time, using the set reference value for the estimated download time. . If the transmission rate calculation unit 152 determines in step S291 that the calculated estimated download time is not equal to or greater than a preset reference value for the estimated download time, the process returns to step S285, and the processes in and after step S285 are repeatedly executed. Is done. On the other hand, if the transmission rate calculation unit 152 determines in step S291 that the calculated estimated download time is greater than or equal to a preset reference value related to the estimated download time, the process proceeds to step S293.

  On the other hand, when the control unit 120 determines in step S284 that the data download mode is not the eco mode 1, the control unit 120 recognizes that the data download mode is the eco mode 2, and the process proceeds to step S296. The processes after step S296 are executed. Then, in step S301, the transmission rate calculation unit 152, based on the content capacity of the data to be downloaded and the estimated transmission rate Er that is predicted, the estimated download time required when data is downloaded (= content capacity / predicted). The estimated transmission rate Er) is calculated. The reference value setting process for the estimated download time in step S302 is the same as the setting process in step S291, and the determination process in step S303 is the same as the determination process in step S292. To do.

If the transmission rate calculation unit 152 determines in step S303 that the calculated estimated download time is not greater than or equal to a preset reference value for the estimated download time, the transmission rate calculation unit 152 calculates the estimated download calculated in step S304. It is determined whether or not the time obtained by adding the time to the current time exceeds the download completion time. In step S304, when the transmission rate calculation unit 152 determines that the time obtained by adding the calculated estimated download time to the current time does not exceed the download completion time, the process returns to step S296, and the processes after step S296 are performed. Repeatedly executed. This

On the other hand, when the transmission rate calculation unit 152 determines in step S304 that the time obtained by adding the calculated estimated download time to the current time exceeds the download completion time, the process proceeds to step S293, and the processes after step S293 are performed. Is executed. Thereby, the mobile communication terminal 101 negotiates with the base station, determines the MCS to be used for communication, and from the base station using the MCS determined by the negotiation with the base station regardless of the reception quality. Force download of data. In step S304, the mobile communication terminal 101 determines whether the time obtained by adding the calculated estimated download time to the current time exceeds the download completion time, but from the download completion time. A certain margin is provided to ensure that the data download is completed before, and the mobile communication terminal 101 adds the calculated estimated download time to the current time so that the margin from the download completion time is a margin. You may make it determine whether the time which subtracted the minute is exceeded.

  In the case of FIG. 23, in calculating the estimated transmission rate Er, correction using the histogram of the MCS level for the other mobile communication terminals 101 is not performed, but as described with reference to FIGS. Alternatively, the estimated download time may be calculated after calculating the estimated transmission rate Er by performing correction using the histogram of the MCS level related to the other mobile communication terminals 101.

[Fourth Embodiment]
By the way, measurement of reception quality (communication quality) is started at an arbitrary timing based on a user's instruction, communication quality MAP associated with position information based on GPS positioning and CQI information (MCS level) is created, and the created communication The quality MAP may be displayed. As a result, the user can easily visually confirm the communication quality in the vicinity of the place where the user is present at an arbitrary timing. Hereinafter, communication quality MAP display processing using this method will be described.

  FIG. 26 shows the internal configuration of the mobile communication terminal 101 according to the fourth embodiment of the present invention. 26 is basically the same as the configuration of the mobile communication terminal 101 according to the first embodiment of the present invention shown in FIG. Components corresponding to those in FIG. 8 are denoted by the same reference numerals, and descriptions of components other than the different components are omitted.

  A GPS wave (GPS information) from a GPS satellite (not shown) is received by the GPS antenna 201. The GPS information includes, for example, transmission time information from each GPS satellite. Thereafter, the GPS information is input to the control unit 120 via the GPS receiving unit 202. And the control part 120 calculates the positional information (latitude / longitude information) which shows the present location of the mobile communication terminal 101 using the acquired GPS information (for example, it can calculate from three to four GPS information). Desirably, position information indicating the current location of the mobile communication terminal 101 is obtained. In general, latitude and longitude are acquired as position information obtained based on GPS information, but address information corresponding to latitude and longitude may be acquired. When acquiring latitude / longitude and address information corresponding to the latitude / longitude, the address information may be obtained by accessing an external server (not shown). Accordingly, the “position information” includes information such as position information (for example, latitude / longitude information) calculated from GPS information and address information corresponding to the information.

  The GPS receiving unit 202 includes a matching circuit and a GPS receiving circuit. The GPS wave (GPS information) received by the GPS antenna 201 is input to the matching circuit of the GPS receiving unit 202. The matching circuit is an element used for improving transmission characteristics in circuits having different impedances, and performs impedance matching processing of GPS waves (GPS information) from the GPS antenna 201. The GPS wave after the impedance matching process is output to the GPS receiving circuit, and the GPS receiving circuit receives the GPS wave (GPS information).

  The communication quality MAP display process in the mobile communication terminal 101 of FIG. 26 will be described with reference to the flowchart of FIG. In the case of FIG. 27, when the user is at the departure point with the mobile communication terminal 101, the user instructs the mobile communication terminal 101 to start CQI measurement, and then the user moves and arrives at the destination. In this case, the mobile communication terminal 101 is instructed to end CQI measurement.

  In step S401, the control unit 120 determines whether or not an instruction to start CQI measurement is received by operating the operation unit 122 by the user, and determines that an instruction to start CQI measurement is received. Wait until. When the control unit 120 determines in step S401 that an instruction to start CQI measurement has been received, the control unit 120 activates the GPS reception unit 202. In step S <b> 203, the control unit 120 acquires position information based on GPS positioning from a GPS satellite (not shown) via the GPS receiving unit 202. Specifically, a GPS wave (GPS information) from a GPS satellite (not shown) is received by the GPS antenna 201. This GPS information includes, for example, transmission time information from each GPS satellite. Thereafter, the GPS information is input to the control unit 120 via the GPS receiving unit 202. The control unit 120 acquires a GPS wave (GPS information) from a GPS satellite (not shown), and calculates position information (latitude and longitude information) indicating the current location of the mobile communication terminal 101 using the acquired GPS information. Then, position information (position information based on GPS positioning) indicating the current location of the mobile communication terminal 101 is obtained. Thereby, the positional information based on GPS positioning is acquired regarding the current location of the mobile communication terminal 101.

  In step S204, the control unit 120 wirelessly measures the SINRs in all resource blocks included in the frequency band used by the base station belonging to the mobile communication system to which the mobile communication terminal 101 is connected. Unit 112 and reception signal processing unit 113 are controlled. The SINR measurement unit 125 is included in a frequency band used by a base station belonging to a mobile communication system to which the mobile communication terminal 101 is connected, with a paging cycle or an integer multiple of a paging cycle (such as 2 or 3). Each RB (resource block) measures the radio channel quality (SINR) related to the received signal from the received signal processing unit 113 and outputs the measurement result of each RB to the CQI information generating unit 126. The CQI information generation unit 126 determines a receivable MCS based on the measurement result by the SINR measurement unit 125 in each RB included in the frequency band used by the base station belonging to the mobile communication system, and determines the determined transmission format Based on (combination of modulation scheme and error correction coding rate), channel state information (CQI information) is generated. The CQI information for each RB includes a CQI Index indicating a combination (MCS) of a modulation scheme and an error correction coding rate, and an MCS level corresponding to the CQI Index. CQI information generation section 126 outputs CQI information for each RB to CQI information control section 127.

  In step S405, the CQI information control unit 127 acquires CQI information for each RB included in the frequency band used by the base station belonging to the mobile communication system to which the mobile communication terminal 101 is connected. Based on the CQI information for each, an estimated MCS level relating to a frequency band used by a base station belonging to the mobile communication system is calculated. The calculation method of the MCS level is basically the same as the calculation method in step S3 in FIG. The CQI information control unit 127 updates the current estimated MCS level stored in the CQI information storage unit 128 based on the calculated MCS level, and sequentially calculates the calculated MCS levels in time series. 128. The CQI information storage unit 128 stores the current estimated MCS level according to the control of the CQI information control unit 127, and sequentially stores the calculated MCS level in time series.

  In step S406, the control unit 120 determines whether or not the MCS level has been calculated N times. If the control unit 120 determines in step S406 that the MCS level has not been calculated N times, the process returns to step S404, the process from step 404 is performed, and the estimated MCS level has been calculated N times. Are executed every predetermined period (a paging period or an integer multiple of the paging period). On the other hand, when the control unit 120 determines in step S406 that the estimated MCS level has been calculated N times, in step S407, the control unit 120 stores the N MCSs stored in the CQI information storage unit 128 in time series. Calculate the average level. In step S408, the control unit 120 causes the storage unit 124 to store the calculated average value of the estimated MCS levels and the position information based on the GPS positioning in association with each other. In step S409, the control unit 120 determines whether or not an instruction to end CQI measurement has been received when the operation unit 122 is operated by the user. If the control unit 120 determines in step S409 that an instruction to end CQI measurement has not been received, the process returns to step S403, and the mobile communication terminal 101 acquires position information based on GPS positioning again. N estimated MCS levels are calculated. Thereby, the acquisition of the position information based on the GPS positioning and the calculation of the estimated MCS level N times are repeatedly performed until an instruction to end the CQI measurement is received.

  If the control unit 120 determines in step S409 that an instruction to end CQI measurement has been received, the control unit 120 in step S410, based on position information based on each GPS positioning acquired by the mobile communication terminal 101, Map information including a user's departure point and destination is acquired from a content server (not shown) via a base station. The map information may be stored in advance in the storage unit 124 of the mobile communication terminal 101. In step S411, the control unit 120 performs communication based on each GPS information stored in the storage unit 124, an MCS level stored in association with each GPS information, and map information acquired from the content server. Create a quality MAP. FIG. 28 shows the communication quality MAP created by the control unit 120. As shown in FIG. 28, the MCS level is “MCS level 12” in the A section (the section from when the user leaves the departure place until 60 (s) elapses), and the B section (the user leaves the departure place). MCS level is “MCS level 8” in the section from 120 (s) to the end of the period, and in section C (section from the user leaving the departure point to 180 (s)), the MCS level is It is “MCS level 15”, and the MCS level is “MCS level 4” in the D section (the section from when the user leaves the departure place until 240 (s) elapses).

  In step S412, the control unit 120 causes the display unit 123 to display the created communication quality MAP. The display unit 123 displays the communication quality MAP under the control of the control unit 120.

  As a result, the user can easily visually confirm the communication quality in the vicinity of the place where the user is present at an arbitrary timing.

  The series of processes described in the embodiments of the present invention can be executed by software, but can also be executed by hardware.

  In the embodiment of the present invention, the steps of the flowchart show an example of processing that is performed in time series in the order described. The processing to be performed is also included.

  Furthermore, the processes explicitly described in the embodiments may be appropriately combined.

  DESCRIPTION OF SYMBOLS 1 ... Base station, 2 (2-1 thru | or 2-2) ... Conventional mobile communication terminal, 11 ... Transmission / reception antenna, 12 ... Radio | wireless part, 13 ... Reception signal processing part, 14 ... Reception data processing part, 15 ... PCM Codec, 16 ... receiver amplifier, 17 ... receiver, 18 ... transmitter amplifier, 19 ... microphone, 20 ... control unit, 21 ... RSSI measuring unit, 22 ... operating unit, 23 ... display unit, 24 ... storage unit, 25 ... SINR Measurement unit, 26 ... CQI information generation unit, 27 ... transmission data processing unit, 28 ... transmission data processing unit, 31 ... demodulation unit, 32 ... rate conversion unit, 33 ... decoding unit, 34 ... error detection unit, 41 ... coding unit , 42 ... Modulation section, 101 ... Mobile communication terminal of the present invention, 111 ... Transmission / reception antenna, 112 ... Radio section, 113 ... Reception signal processing section, 114 ... Reception data processing section, 115 ... PCM codec, 116 ... Increase in reception 117, receiver, 118, transmission amplifier, 119, microphone, 120, control unit, 121 ... RSSI measurement unit, 122 ... operation unit, 123 ... display unit, 124 ... storage unit, 125 ... SINR measurement unit, 126 ... CQI information generation unit, 127 ... CQI information control unit, 128 ... CQI information storage unit, 129 ... transmission data processing unit, 130 ... transmission data processing unit, 131 ... demodulation unit, 132 ... rate conversion unit, 133 ... decoding unit, 134 DESCRIPTION OF SYMBOLS ... Error detection part 141 ... Coding part 142 ... Modulation part 151 ... Assignment information acquisition part 152 ... Transmission rate calculation part 153 ... Transmission rate information storage part 201 ... GPS antenna 202 ... GPS reception part

Claims (23)

A transmission / reception means for transmitting / receiving a radio signal between a mobile communication terminal and a base station belonging to the mobile communication system;
Signal processing means for processing radio signals transmitted and received between the mobile communication terminal and a base station belonging to the mobile communication system;
One of MCSs, which is a combination of a modulation scheme and an error correction coding rate, determined in advance according to a transmission path state between the mobile communication terminal and a base station belonging to the mobile communication system. Communication control for determining communication with the base station belonging to the mobile communication system and controlling communication between the mobile communication terminal and the base station belonging to the mobile communication system using the determined MCS Means,
Reception quality detecting means for detecting reception quality of a radio signal from a base station belonging to the mobile communication system on which the mobile communication terminal is waiting;
For each resource block included in a frequency band used by a base station belonging to the mobile communication system, an MCS level of the MCS based on the reception quality detected by the reception quality detection means in a plurality of MCSs. Generating means for generating channel state information including:
When the mobile communication terminal is waiting for a base station belonging to the mobile communication system, based on the channel state information for each resource block generated by the generation unit, the mobile communication terminal Calculating means for calculating an estimated MCS level at the mobile communication terminal when performing data communication with a base station belonging to the mobile communication system;
A mobile communication terminal comprising display means for displaying an estimated MCS level calculated by the calculation means. Among the estimated MCS levels calculated within the past predetermined time by the calculating means, storage means for storing the maximum estimated MCS level and the minimum estimated MCS level;
And a determination unit that determines whether the estimated MCS level calculated by the calculation unit is larger than the maximum estimated MCS level stored by the storage unit or smaller than the minimum estimated MCS level. ,
When the estimated MCS level calculated by the calculating means is larger than the maximum estimated MCS level stored by the storage means, the maximum estimated MCS level is updated to the estimated MCS level calculated by the calculating means. When the estimated MCS level calculated by the calculating means is smaller than the minimum estimated MCS level stored by the storage means, the minimum estimated MCS level is updated to the estimated MCS level calculated by the calculating means The mobile communication terminal according to claim 1, wherein:   The mobile communication according to claim 2, further comprising initialization means for initializing the maximum estimated MCS level and the minimum estimated MCS level stored by the storage means every predetermined time. Terminal.   When the MCS level related to MCS determined between the base station belonging to the mobile communication system by the communication control means is different from the estimated MCS level displayed by the display means, the estimated MCS displayed by the display means The mobile communication terminal according to claim 1, further comprising updating means for updating a level to an MCS level related to MCS determined with a base station belonging to the mobile communication system.   The calculating means calculates an average value or maximum level of estimated MCS levels included in the channel state information for each resource block generated by the generating means, and a base station to which the mobile communication terminal belongs to the mobile communication system. The mobile communication terminal according to claim 1, wherein the mobile communication terminal is calculated as an estimated MCS level at the mobile communication terminal when data communication is performed.   The mobile communication terminal further comprises setting means for setting a download mode when downloading data to the first mode or the second mode when performing data communication with a base station belonging to the mobile communication system. The mobile communication terminal according to claim 1, wherein:   When the download mode set by the setting means is the first mode, and the estimated MCS level calculated by the calculating means is equal to or higher than a preset reference value, the communication control means And a base station belonging to the mobile communication system as one of the MCSs that is a combination of the error correction coding rate, and using the determined MCS, data download is started, 7. The mobile communication terminal according to claim 6, wherein when the estimated MCS level calculated by the calculating means is not equal to or higher than a preset reference value, data download is not started.   The apparatus further comprises setting means for setting the reference value to an MCS level that is at least one step higher than a minimum estimated MCS level among estimated MCS levels calculated within the past predetermined time by the calculating means. The mobile communication terminal according to claim 7. A transmission / reception means for transmitting / receiving a radio signal between a mobile communication terminal and a base station belonging to the mobile communication system;
Signal processing means for processing radio signals transmitted and received between the mobile communication terminal and a base station belonging to the mobile communication system;
One of MCSs, which is a combination of a modulation scheme and an error correction coding rate, determined in advance according to a transmission path state between the mobile communication terminal and a base station belonging to the mobile communication system. Communication control for determining communication with the base station belonging to the mobile communication system and controlling communication between the mobile communication terminal and the base station belonging to the mobile communication system using the determined MCS Means,
Reception quality detecting means for detecting reception quality of a radio signal from a base station belonging to the mobile communication system on which the mobile communication terminal is waiting;
For each resource block included in a frequency band used by a base station belonging to the mobile communication system, an MCS level of the MCS based on the reception quality detected by the reception quality detection means in a plurality of MCSs. Generating means for generating channel state information including:
Of broadcast information or downlink resource allocation information from a base station belonging to the mobile communication system, a frequency bandwidth used by a base station belonging to the mobile communication system, and a base station on which the mobile communication terminal is waiting Detecting means for detecting the number of other mobile communication terminals during data communication or negotiation during data communication;
Based on the frequency bandwidth detected by the detection means, and the number of other mobile communication terminals in negotiation with the base station on which the mobile communication terminal is awaiting data communication or data communication, A congestion degree calculating means for calculating a congestion degree relating to a base station belonging to the mobile communication system;
When the mobile communication terminal is waiting for a base station belonging to the mobile communication system, based on the channel state information for each resource block generated by the generation unit, the mobile communication terminal Estimated MCS level calculating means for calculating an estimated MCS level in the mobile communication terminal when performing data communication with a base station belonging to the mobile communication system;
Based on the estimated MCS level calculated by the estimated MCS level calculation means and the congestion degree calculated by the congestion degree calculation means, the mobile communication terminal and the base station belonging to the mobile communication system and data communication Estimated transmission rate calculation means for calculating an estimated transmission rate in the case of
A mobile communication terminal comprising: display means for displaying the estimated transmission speed calculated by the estimated transmission speed calculation means. Storage means for storing the maximum estimated transmission speed and the minimum estimated transmission speed among the estimated transmission speeds calculated within the past predetermined time by the estimated transmission speed calculation means,
A determination unit that determines whether the estimated transmission rate calculated by the estimated transmission rate calculation unit is larger than the maximum estimated transmission rate stored in the storage unit or smaller than the minimum estimated transmission rate; Further comprising
When the estimated transmission rate calculated by the estimated transmission rate calculation unit is larger than the maximum estimated transmission rate stored by the storage unit, the maximum estimated transmission rate is calculated by the estimated transmission rate calculation unit. When the estimated transmission rate updated to the estimated transmission rate and calculated by the estimated transmission rate calculation unit is smaller than the minimum estimated transmission rate stored by the storage unit, the minimum estimated transmission rate is the estimated transmission rate. The mobile communication terminal according to claim 9, wherein the mobile communication terminal is updated to an estimated transmission rate calculated by a rate calculation unit.   11. The mobile communication according to claim 10, further comprising initialization means for initializing the maximum estimated transmission rate and the minimum estimated transmission rate stored by the storage unit at each predetermined time. Terminal.   The apparatus further comprises setting means for setting the predetermined time for initializing the maximum estimated transmission speed and the minimum estimated transmission speed stored by the storage means by the initialization means to an arbitrary time. The mobile communication terminal according to claim 11.   The generating means generates the channel state information for each resource block included in a frequency band used by a base station belonging to the mobile communication system at every paging cycle or an integer multiple of a paging cycle. A mobile communication terminal according to any one of claims 1 and 9. Based on the MCS level related to MCS determined between the base station belonging to the mobile communication system by the communication control means and the amount of radio resources allocated to the mobile communication terminal by the base station belonging to the mobile communication system A transmission rate calculation means for data communication for calculating a transmission rate during data communication;
When the transmission speed at the time of data communication calculated by the transmission speed calculation means at the time of data communication and the estimated transmission speed displayed by the display means are different from each other, The mobile communication terminal according to claim 9, further comprising an updating unit that updates the transmission rate during data communication calculated by the rate calculating unit.   The estimated MCS level calculation means indicates the average value or maximum level of MCS levels included in the channel state information for each resource block generated by the generation means, so that the mobile communication terminal belongs to the mobile communication system. The mobile communication terminal according to claim 9, wherein the mobile communication terminal is calculated as an estimated MCS level at the mobile communication terminal when data communication is performed with a base station. The detecting means detects an MCS level used by another mobile communication terminal during data communication or negotiation during data communication with a base station on which the mobile communication terminal is waiting,
The mobile communication terminal is
Creating means for creating a frequency distribution relating to the MCS level used by the other mobile communication terminal detected by the detecting means;
Based on the frequency distribution created by the creating unit and the estimated MCS level calculated by the estimated MCS level calculating unit, a correction coefficient for correcting the estimated transmission rate calculated by the estimated transmission rate calculating unit is calculated. Correction coefficient calculation means for
The moving body according to claim 9, further comprising a correction unit that corrects the estimated transmission rate calculated by the estimated transmission rate calculation unit using the correction coefficient calculated by the correction factor calculation unit. Communication terminal.   The mobile communication terminal further comprises setting means for setting a download mode when downloading data to the first mode or the second mode when performing data communication with a base station belonging to the mobile communication system. The mobile communication terminal according to claim 9, wherein the mobile communication terminal is a mobile communication terminal. Estimation for calculating an estimated download time required to download data based on the estimated transmission rate calculated by the estimated transmission rate calculation means and the content capacity of the data downloaded from the base station belonging to the mobile communication system A download time calculating means;
When the download mode set by the setting means is the first mode, when the estimated download time calculated by the estimated download time calculating means is greater than or equal to a preset reference value, the communication control means The MCS, which is a combination of the modulation scheme and the error correction coding rate, is determined with the base station belonging to the mobile communication system, and data download is started using the determined MCS. 18. The mobile communication terminal according to claim 17, wherein when the estimated download time calculated by the estimated download time calculating means is not greater than a preset reference value, data download is not started. The detecting means detects an MCS level used by another mobile communication terminal during data communication or negotiation during data communication with a base station on which the mobile communication terminal is waiting,
The mobile communication terminal is
Creating means for creating a frequency distribution relating to the MCS level used by the other mobile communication terminal detected by the detecting means;
Correction coefficient calculating means for calculating a correction coefficient for correcting the estimated transmission rate based on the frequency distribution created by the creating means and the estimated MCS level calculated by the estimated MCS level calculating means;
Correction means for correcting the estimated transmission rate calculated by the estimated transmission rate calculation unit using the correction coefficient calculated by the correction factor calculation unit;
Estimated download time for calculating the estimated download time required to download data based on the estimated transmission rate corrected by the correcting means and the content capacity of the data downloaded from the base station belonging to the mobile communication system And a calculating means,
When the download mode set by the setting means is the first mode, when the estimated download time calculated by the estimated download time calculating means is greater than or equal to a preset reference value, the communication control means The MCS, which is a combination of the modulation scheme and the error correction coding rate, is determined with the base station belonging to the mobile communication system, and data download is started using the determined MCS. 18. The mobile communication terminal according to claim 17, wherein when the estimated download time calculated by the estimated download time calculating means is not greater than a preset reference value, data download is not started. Received signal strength measuring means for measuring a signal strength of a received signal from a base station belonging to the mobile communication system;
20. The mobile communication according to claim 18, further comprising setting means for setting the reference value based on the signal strength of the received signal measured by the received signal strength measuring means. Terminal. Counting means for counting the frequency of switching base stations belonging to the mobile communication system or the frequency of searching for base stations;
20. The setting means for setting the reference value based on the frequency of switching the base station or the frequency of searching for a base station counted by the counting means. Mobile communication terminals. A transmission / reception step of transmitting / receiving a radio signal between a mobile communication terminal and a base station belonging to the mobile communication system;
A signal processing step of processing a radio signal transmitted and received between the mobile communication terminal and a base station belonging to the mobile communication system;
One of MCSs, which is a combination of a modulation scheme and an error correction coding rate, determined in advance according to a transmission path state between the mobile communication terminal and a base station belonging to the mobile communication system. Communication control for determining communication with the base station belonging to the mobile communication system and controlling communication between the mobile communication terminal and the base station belonging to the mobile communication system using the determined MCS Steps,
A reception quality detection step of detecting a reception quality of a radio signal from a base station belonging to the mobile communication system on which the mobile communication terminal is waiting;
For each resource block included in the frequency band used by the base station belonging to the mobile communication system, the MCS of the MCS based on the reception quality detected by the processing of the reception quality detection step in a plurality of MCSs A generating step for generating channel state information including a level;
When the mobile communication terminal is waiting for a base station belonging to the mobile communication system, based on the channel state information for each resource block generated by the processing of the generation step, the mobile communication A calculation step of calculating an estimated MCS level at the mobile communication terminal when the terminal performs data communication with a base station belonging to the mobile communication system;
A communication quality display method, comprising: a display step of displaying an estimated MCS level calculated by the processing of the calculation step. A transmission / reception step of transmitting / receiving a radio signal between a mobile communication terminal and a base station belonging to the mobile communication system;
A signal processing step of processing a radio signal transmitted and received between the mobile communication terminal and a base station belonging to the mobile communication system;
One of MCSs, which is a combination of a modulation scheme and an error correction coding rate, determined in advance according to a transmission path state between the mobile communication terminal and a base station belonging to the mobile communication system. Communication control for determining communication with the base station belonging to the mobile communication system and controlling communication between the mobile communication terminal and the base station belonging to the mobile communication system using the determined MCS Steps,
A reception quality detection step of detecting a reception quality of a radio signal from a base station belonging to the mobile communication system on which the mobile communication terminal is waiting;
For each resource block included in the frequency band used by the base station belonging to the mobile communication system, the MCS of the MCS based on the reception quality detected by the processing of the reception quality detection step in a plurality of MCSs A generating step for generating channel state information including a level;
Of broadcast information or downlink resource allocation information from a base station belonging to the mobile communication system, a frequency bandwidth used by a base station belonging to the mobile communication system, and a base station on which the mobile communication terminal is waiting A detection step of detecting the number of other mobile communication terminals during data communication or negotiation during data communication;
Based on the frequency bandwidth detected by the processing of the detection step and the number of other mobile communication terminals that are in data communication or negotiation during data communication with the base station on which the mobile communication terminal is waiting A congestion degree calculating step for calculating a congestion degree related to a base station belonging to the mobile communication system;
When the mobile communication terminal is waiting for a base station belonging to the mobile communication system, based on the channel state information for each resource block generated by the processing of the generation step, the mobile communication An estimated MCS level calculating step for calculating an estimated MCS level at the mobile communication terminal when the terminal performs data communication with a base station belonging to the mobile communication system;
Based on the estimated MCS level calculated by the processing of the estimated MCS level calculation step and the congestion level calculated by the congestion level calculation means, the mobile communication terminal is connected to a base station belonging to the mobile communication system. An estimated transmission rate calculating step for calculating an estimated transmission rate in the case of data communication;
And a display step for displaying an estimated transmission rate calculated by the process of the estimated transmission rate calculating step.

Images