RU2619776C1 - Radio terminal, radio communication system and radio communication method - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: communication unit of the radio terminal performs radio measurement for the base station and paging signal tracking during a periodic interval of time. The controller manages the communication unit to perform filtering radio measurements within a time period with the intervals which are less than half of the time period.

EFFECT: improved measurement accuracy for cell detection with higher radio communication quality.

5 cl, 24 dwg

Description

FIELD OF TECHNOLOGY

The embodiments discussed herein relate to a radio terminal that provides radio communications, a radio communications system, and a radio communications method.

BACKGROUND

Cellular mobile communications evolved from UMTS (Universal Mobile Telecommunications System) to LTE (Long-Term Development Standard). In LTE, an OFDM (Orthogonal Frequency Division Multiplexing) based system is indicated as a radio access technology, and high-speed wireless packet communication is provided with a peak transmission rate of 100 Mbps or more in a downlink and a peak transmission rate of 50 Mbps or more in uplink.

3GPP (3rd Generation Partnership Systems Project), an international standardization organization, is currently launching LTE-based LTE-A (LTE Enhanced LTE) research to enable higher-speed communications. LTE-A targets the downlink peak transmission rate of 1 Gbps and the uplink peak transmission rate of 500 Mbps, and various new technologies such as radio access system and network architecture are being studied (e.g. see NPTL 1 - NPTL 3). LTE-A, on the other hand, is an LTE-based system, and therefore it is important to maintain backward compatibility.

In LTE or LTE-A, a cell selection is specified as a standby operation of a radio terminal. In particular, cell selection and cell reselection are defined (see, for example, NPTL 4 and NPTL 5).

Cell selection is performed when the radio terminal turns on the power and PLMN is selected (Public Land Mobile Network: Mobile Operator). As the cell selection, the cell selection (primary cell selection) performed by the radio terminal without knowledge of the cell information and the cell selection (cell selection having the stored information) performed by the mobile station in the presence of cell information are set.

When selecting a cell, the radio terminal measures the radio quality and selects a cell with good radio quality as the serving cell and is based on the network. Namely, if the “S” criteria for selecting a cell, determined using RSRP (Received Reference Power) and RSRQ (Received Quality of the Reference Signal), can be based on the cell (for example, see NPTL 4). The radio terminal can receive an incoming call based on the network. Cell reselection is performed to detect a cell with higher radio quality, and when a higher radio quality is detected, the radio terminal is based in the cell.

Standby radio measurement is set to detect cells with higher radio quality (see, for example, NPTL 5). In standby mode, it is necessary to achieve a balance between the energy consumption of the radio terminal and the accuracy of radio measurements.

For example, if the measurement frequency is reduced to reduce energy consumption, the accuracy of the measurements is degraded, and there may be a case where it is not possible to base in the corresponding cell. On the other hand, if the measurement frequency increases to improve measurement accuracy, energy consumption increases. In view of this, DRX (Intermittent Reception) is specified (see, for example, NPTL 5).

There are cases where the DRX cycle value is obtained using the broadcast information transmitted by the base station, and when it is set using the NAS (Non-Access Layer), which is the upper level. The radio terminal measures at least once for each DRX and measures the quality of the radio communication. The radio terminal then averages the radio quality in accordance with the measurement intervals indicated by the DRX function, and then calculates the measured value of the radio quality.

In addition, the standby radio periodically monitors the paging signal to detect an incoming call. In the radio terminal, as in the case of the measurement described above, if the tracking frequency of the paging signal decreases, communication delay occurs, and if the tracking frequency of the paging signal increases, energy consumption increases. Therefore, it is specified that the paging signal is tracked only once per DRX cycle (see, for example, NPTL 4).

As described above, the radio terminal can perform cell selection and incoming call detection based on energy consumption by measuring and tracking the paging signal during a DRX cycle, which is a measurement cycle.

LIST OF BIBLIOGRAPHIC REFERENCES

Non-Patent Literature

SUMMARY OF THE INVENTION

Technical challenge

The decision is made whether to measure and select a cell is made at least once for each DRX cycle. In addition, it was specified that the measurement values (in particular, the RSRP and RSRQ values) of the radio quality obtained by measurements are filtered and averaged, where the measurement values are spaced at least half the DRX duration when calculating the measured measurement value (see, e.g. NPTL 5).

Therefore, if the DRX cycle is extended to reduce the energy consumption of the radio terminal, the measurement measurement interval is extended, and there was such a problem that the accuracy of the measurements is impaired.

THE SOLUTION OF THE PROBLEM

To solve the above problem, a radio terminal is provided that communicates with the base station. The radio terminal has a communication unit configured to perform radio measurements for the base station and tracking the paging signal for a period of time, and a controller configured to control the communication unit to perform filtering of radio measurements over a period of time at intervals of less than half the time interval.

USEFUL EFFECTS OF THE INVENTION

According to the disclosed apparatus and method, measurement degradation can be reduced.

The above and other objects, characteristics and advantages of the present embodiments will be explained with the help of the following explanation in conjunction with the accompanying drawings, illustrating preferred embodiments as examples of the present embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 explains a radio terminal in accordance with a first embodiment.

FIG. 2 depicts a radio communication system in accordance with a second embodiment.

FIG. 3 is a functional block diagram of a radio terminal.

FIG. 4 depicts an example hardware configuration of a radio terminal.

FIG. 5 is a functional block diagram of a base station.

FIG. 6 depicts an example hardware configuration of a base station.

FIG. 7 is part 1 of a radio terminal timing chart.

FIG. 8 is part 2 of a radio terminal timing chart.

FIG. 9 is a flowchart of a radio terminal.

FIG. 10 is a flowchart of a base station.

FIG. 11 is a timing chart of a radio terminal in accordance with a third embodiment.

FIG. 12 explains a DRX mask pattern.

FIG. 13 is a flowchart of a radio terminal.

FIG. 14 is a flowchart of a base station.

FIG. 15 is a timing chart of a radio terminal in accordance with a fourth embodiment.

16 is a flowchart of a radio terminal.

FIG. 17 is a flowchart of a base station.

FIG. 18 is a timing chart of a radio terminal in accordance with a fifth embodiment.

FIG. 19 is a flowchart of a radio terminal.

FIG. 20 is a flowchart of a base station.

FIG. 21 is a timing chart of a radio terminal in accordance with a sixth embodiment.

FIG. 22 explains the operations of the NAS Attach procedure and the NAS detach procedure.

FIG. 23 is a flowchart of a radio terminal.

FIG. 24 is a flowchart of a base station.

DESCRIPTION OF EMBODIMENTS

Next, with reference to the drawings, embodiments are explained in detail.

(First Embodiment)

FIG. 1 explains a radio terminal in accordance with a first embodiment. As shown in FIG. 1, the radio terminal 1 has a communication unit 1a and a controller 1b. Arrows A1-A3 shown in FIG. 1 indicate timing of measurements of a base station not shown, and timing of tracking a paging signal performed by radio terminal 1. FIG. 1 m indicates timing for measurement of a base station not shown, and p indicates timing for tracking a paging signal performed by radio terminal 1.

The communication unit 1a periodically performs a measurement of a base station not shown and tracking the paging signal for a period of time T.

For example, T shown in FIG. 1, stands for DRX. The communication unit 1a periodically measures (m) the base station and tracks the paging signal (p) during the DRX DRX cycle.

The controller 1b controls the communication unit 1a to perform the measurement during the time interval T at intervals of less than half the time interval T. In addition, it is also possible to filter the measurement values (in particular, RSRP and RSRQ) of the radio quality obtained by measurement, where measurement values are spaced less than half the time T.

For example, as indicated by arrow A1, the controller 1b controls the communication unit 1a to perform a measurement, wherein the measurement values are spaced less than half the time T. In particular, the controller 1b controls the communication unit 1a to perform a measurement, with the measurement values spaced less than half the DRX cycle.

Arrow A2 indicates an example of traditional timing for measuring and tracking a paging signal. As described above, it is determined that the decision on whether to perform measurement and cell selection is performed at least at intervals of the DRX cycle. Here, in order to reduce the energy consumption of the radio terminal 1, the duration (DRX cycle) of the time period T is increased, as indicated by arrow A3.

Arrow A3 indicates another example of traditional timing for measuring and tracking a paging signal. Without violating the specifications, the measurement is performed at intervals equal to half the DRX cycle (DRX / 2 cycle). In addition, when calculating the measured measurement values, the measurement measurement values are averaged, and the averaged values are the result of measuring the radio quality of each cell. By performing the measurement and calculating the measured values, it is possible to maintain the accuracy of the measurements, even if the duration (DRX cycle) of the time interval T increases. However, the traditional measurement interval increases as the DRX cycle increases, and therefore the measurement averaging interval increases and the measurement accuracy deteriorates.

In contrast, as described above, the controller 1b controls the communication unit 1a to take measurements at intervals of less than half the length of the time T. In addition, also when filtering measurement values (in particular, RSRP and RSRQ values) of the radio quality obtained from using measurements, it is possible to perform filtering when the measurement values are spaced at intervals of less than half the duration. Due to this, the radio terminal 1 can shorten the measurement averaging interval, as well as reduce energy consumption, and can reduce the deterioration of measurements.

As described above, the communication unit 1a of the radio terminal 1 measures the base station and monitors the paging signal for a period of time T. Then, the controller 1b controls the unit 1a for measuring at intervals of less than half the duration of the time interval T within the time interval T. Due to this, the radio terminal 1 can prevent an increase in the measurement interval, and can reduce the deterioration of the measurement, even if the length of the time interval T is increased to reduce consumption energy.

(Second Embodiment)

Next, with reference to the drawings, a second embodiment is explained.

FIG. 2 depicts a radio communication system in accordance with a second embodiment. FIG. 2 shows a base station 11 and a radio terminal 12. A base station 11 and a radio terminal 12 carry out radio communication using an LTE or LTE-A communication system.

The radio terminal 12 is integrated in a device such as a gas flow meter and an electric meter. The radio terminal 12 transmits information, such as an anomaly and usage charges, detected by the device, for example, a gas flow meter and an electric meter, to base station 11. The information transmitted to the base station 11 is transmitted, for example, to a gas company or an electric power company.

The device described above has communication characteristics different from those of a mobile phone, etc. For example, the device does not move, and the communication volumes are small. Therefore, it is believed that the device is in standby mode most of the time and rarely enters connected mode.

In the case where the device is installed in a private apartment, etc., the base station 11 may be, for example, a home eNB (Advanced Node B). In addition, the device can be integrated into a sensor or health indicator to control a person’s health status, not limited to the measuring device described above.

FIG. 3 is a functional block diagram of a radio terminal. As shown in FIG. 3, the radio terminal 12 has a communication unit 21 and a controller 22. The controller 22 has a radio controller 22a, a control plane level controller 22b, and an application level controller 22c.

The communication unit 21 performs radio control. For example, the communication unit 21 performs baseband (BB) processing and radio frequency (RF) processing of the signal transmitted to and received from the base station 11. In addition, the power of the communication unit 21 is turned on and off by controlling the radio controller 22a of the controller 22.

The radio controller 22a controls the BB processing and RF processing of the communication unit 21. In addition, the radio controller 22a performs power on and off control of the communication unit 21.

The control plane layer controller 22b controls the RRC (Radio Resource Control) level and the NAS level.

The application layer controller 22c performs application level control.

The communication unit 21 corresponds, for example, to the communication unit 1a in FIG. 1. The radio controller 22a and the control plane level controller 22b correspond, for example, to the controller 1b in FIG. one.

FIG. 4 depicts an example hardware configuration of a radio terminal. As shown in FIG. 4, the radio terminal 12 has a processor 31, a main memory 32, a ROM (read only memory) 33, a drive 34, a communication interface 35, an input and output device 36, a display 37, and a bus 38.

The processor 31, the main memory 32, ROM 33, the drive 34, the communication interface 35, the input and output device 36 and the display 37 are connected via a bus 38. The entire radio terminal 12 is controlled by a processor 31. The processor 31 is, for example, a CPU (central processor) or DSP (digital signal processor).

The main memory 32 temporarily stores data and programs used in various types of processing of the processor 31. In the ROM 33, static information, such as a protocol, is stored to set the operation of the radio terminal 12. For example, information is stored in the ROM 33 for the processor 31 to perform plane processing data processing control plane processing planning, etc. The drive 34 stores data and programs used in various types of processing of the processor 31. The communication interface 35 communicates with the base station 11. For example, the communication interface 35 converts the baseband signal into a radio frequency and outputs a radio frequency to an antenna that is not shown. In addition, the communication interface 35 converts in frequency the radio signal received by an antenna, which is not shown, into a baseband signal.

The input and output device 36 is, for example, a key, a speaker or a microphone. For example, a key accepts a character or number entered by the user. The loudspeaker, for example, converts the speech signal received from the base station 11 into speech and outputs the speech. The microphone converts the user's speech into an electrical signal. The display 37 is, for example, an LCD (liquid crystal display). The display 37 displays, for example, data received from the base station 11.

The function of the communication unit 21 in FIG. 3 is implemented, for example, using the communication interface 35. The function of the controller 22 is implemented, for example, using the processor 31.

FIG. 5 is a functional block diagram of a base station. As shown in FIG. 5, the base station 11 has a communication unit 41 and a controller 42. The controller 42 has a radio controller 42a and a control plane level controller 42b.

The communication unit 41 controls radio communication. For example, the communication unit 41 performs BB processing and radio frequency (RF) processing of the signal transmitted to and received from the radio terminal 12.

The radio controller 42a controls the processing of the BB and the RF processing of the communication unit 41.

The control plane layer controller 42b controls the RRC level and the NAS level.

FIG. 6 depicts an example hardware configuration of a base station. As shown in FIG. 6, base station 11 has a processor 51, main memory 52, ROM 53, storage 54, communication interface 55 and bus 56.

The processor 51, the main memory 52, ROM 53, the drive 54 and the communication interface 55 are connected via a bus 56. The entire base station 11 is controlled by a processor 51. The processor 51 is, for example, a CPU or DSP.

The main memory 52 temporarily stores data and programs used in various types of processing of the processor 51. In ROM 53, static information, such as a protocol for setting the operation of the base station 11, is stored. For example, information for the processor 51 for processing the data plane is stored in ROM 53 processing the control plane, processing planning, etc. The drive 54 stores data and programs used in various types of processing of the processor 51. The communication interface 55 communicates with the radio terminal 12. For example, the communication interface 55 converts a baseband signal to a radio frequency and outputs a radio frequency to an antenna that is not shown. In addition, the communication interface 55 converts in frequency the radio signal received by an antenna, which is not shown, into a baseband signal. In addition, the communication interface 55 carries out wired communication with a high-level device, such as an S-GW (Serving Gateway).

FIG. 7 is part 1 of a radio terminal timing chart. In FIG. 7 m denotes the timing of the measurement of the radio terminal 12. In addition, p denotes the timing of the tracking signal of the search signal of the radio terminal 12.

In the example of FIG. 7, the timings m and p before and after the event detected by the application layer are different. An event occurs, for example, when reporting a charge from an electric meter, etc. and an anomaly report.

The radio terminal 12 uses a long DRX cycle longer than a normal DRX cycle, for example, to reduce power consumption.

Here, the measured value of a conventional measurement is calculated by averaging the measurement measurements with an interval of at least “DRX / 2 cycle”. Therefore, the measurement interval is increased, for example, as indicated by arrow A3 in FIG. 1, and measurement accuracy is deteriorating.

In contrast, in the radio terminal 12, the measurement is performed at least once during the DRX time span. Therefore, it is possible to measure many times during the DRX time span. However, the measured value is calculated by filtering the measurement values of the measurements, while the measurement values are located at the interval "long DRX / n cycle" (n> 2). Therefore, the radio terminal 12 measures at intervals of “X” shown in FIG. 7.

The radio terminal 12 calculates the measured measurement value, for example, by averaging two measurements. For example, the radio terminal 12 calculates the measured value using the measurement values of the two measurements m on the left side and m on the right side in the long DRX cycle before the event of FIG. 1. In addition, the radio terminal 12 calculates the measured value using the measurement values of the measurements of the first m and second m on the left in the long DRX cycle after the event. In addition, the radio terminal 12 calculates the measured value using the measurement measurements of the third m and the fourth m to the left.

After the event, the number of measurements during the long DRX cycle increased compared to that before the event. For example, in FIG. 7 before the event, the number of measurements is two, and after the event, the number is four. The reason for this is that basing in the corresponding cell and corresponding notification of event information for the base station are achieved by increasing the number of measurements to improve the accuracy of the measurement estimate. When determining that it is not possible to connect to the previous cell by measuring after the occurrence of the event, the radio terminal 12 selects a cell to try to detect a new cell. In addition, after transmitting UL data for the event, the radio terminal 12 returns to work before the event.

FIG. 8 is part 2 of a radio terminal timing chart. In the timing diagram of FIG. 8, the measurement interval after the occurrence of the event, that is, the Y interval, is short relative to the timing chart in FIG. 7. In other words, in FIG. 8, the measurement frequency is increased compared to FIG. 7. Because of this, the energy consumption of the radio terminal 12 is increased compared to FIG. 7, and the measurement accuracy improves because when calculating the measured measurement value, the interval over which each measurement is averaged is reduced.

However, this does not mean that the shorter the averaging interval, the higher the measurement accuracy when calculating the measured measurement value. If the averaging interval is too small, it is likely that the estimate was made only at the moment of good propagation conditions of the radio waves, or vice versa, the probability that the estimate was made only at the time of poor propagation conditions of radio waves. Therefore, it is recommended to set the interval between each measurement while maintaining a certain interval. For example, in FIG. 7, the measurement filtering interval is set to “X / 2”, and in FIG. 8, the measurement filtering interval is set to “Y / 2”.

It should be noted that the radio terminal 12 may resume the normal measurement interval after the event. For example, the radio terminal 12 may measure at intervals of the “DRX / 2 cycle” after the occurrence of the event.

The following explains obtaining n, which determines the measurement interval. For example, n is reported by the base station 11 using broadcast information.

In particular, after power-up, the radio terminal 12 performs a primary cell search and is based in a cell with good radio quality (suitable cell). At this time, the radio terminal 12 performs the NAS Attach procedure. Based on the cell, the radio terminal 12 receives the broadcast information of the cell from the base station 11 and obtains n from the received broadcast information. Due to this, the radio terminal 12 can calculate the measurement interval.

As shown in FIG. 8, when the measurement interval changes after the occurrence of the event, the radio terminal 12 can notify the base station 11 that an event has occurred, and the base station 11 can notify the radio terminal 12 of a new n. Base station 11 may also change n according to, for example, the type of event (for example, if the event is an emergency).

In addition, n may be determined in advance or may be calculated by the identifier (ID) of the device. For example, the device ID is indicated using a 12 bit value. The radio terminal 12 may divide the device ID of the radio terminal 12, for example, by an appropriate value, such as 4000, and may set the remainder to n.

The base station 11 may also notify the radio terminal 12 of the number of measurements during the long DRX cycle using broadcast information. In addition, the base station 11 can notify about the number of measurements during a long DRX cycle when receiving an event notification from the radio terminal 12.

FIG. 9 is a flowchart of a radio terminal.

(Step S1) The power of the radio terminal 12 is turned on.

(Step S2) The control plane level controller 22b receives broadcast information from the base station 11. In other words, the control plane level controller 22b receives “n”, which is used to calculate the measurement interval.

(Step S3) The control plane layer controller 22b performs the NAS Attach procedure.

(Step S4) The control plane level controller 22b calculates a measurement interval from the received “n”. The radio controller 22a turns the communication unit 21 on and off to measure at intervals computed by the control plane level controller 22b. The control plane level controller 22b averages the measured measurements to evaluate their quality.

The control plane level controller 22b performs paging tracking, for example, with timing that satisfies the following expression.

SFN is the system frame number. T is a DRX cycle (long DRX cycle). The UE-ID is the radio terminal ID. N is a value determined by a DRX cycle.

(Step S5) The controller 22 from the application layer expects an event.

(Step S6) The controller 22 from the application layer determines whether an event has occurred. If an event has occurred, the controller 22 from the application layer proceeds to step S7. If the event did not occur, the controller 22 from the application layer proceeds to step S5.

(Step S7) The control plane level controller 22b and the radio controller 22a measure with the new settings and evaluate its quality. For example, the control plane level controller 22b performs measurement with new settings, as explained in FIG. 8. The control plane level controller 22b may perform a measurement as shown in FIG. 7.

FIG. 10 is a flowchart of a base station.

(Step S11) The control plane level controller 42b notifies the radio terminal 12 of broadcast information via the radio controller 42a. The broadcast information includes “n”, which is used to calculate the measurement interval.

(Step S12) The control plane layer controller 42b performs the NAS Attach procedure.

(Step S13) The control plane level controller 42b awaits an event report from the radio terminal 12.

(Step S14) The control plane level controller 42b determines whether an event report has been received from the radio terminal 12. In the event that the event report from the radio terminal 12 is received, the control plane level controller 42b proceeds to step S15. In the event that an event report from the radio terminal 12 is not received, the control plane level controller 42b proceeds to step S13.

(Step S15) The control plane level controller 42b notifies the radio terminal 12 of a new “n”.

As described above, the control plane level controller 22b and the radio controller 22a control the communication unit 21 to perform measurement filtering, during a long DRX cycle, at intervals of less than half the length of a long DRX cycle. Due to this, the radio terminal 12 can reduce the increase in the measurement interval and can reduce the deterioration of measurement accuracy, even if you use a long DRX cycle to reduce energy consumption.

In addition, the control plane level controller 22b and the radio controller 22a after the occurrence of the event increase the number of measurements during the long DRX cycle compared to that before the event. Due to this, the radio terminal 12 can improve the quality of the measurement.

In addition, the control plane level controller 22b and the radio controller 22a after the occurrence of the event reduce the measurement interval compared to that before the event. Due to this, the radio terminal 12 can improve the quality of the measurement.

(Third Embodiment)

Next, a third embodiment is explained in detail with reference to the drawings. In a third embodiment, masking is applied to the traditional DRX to provide a length of time in which DRX is not performed and DRX is performed periodically. Although traditional DRX can be performed at a time interval in which DRX is performed, to improve measurement quality, it is also possible to measure many times during a DRX cycle and filter the measurement at intervals of less than half the length of the DRX cycle.

It should be noted that the radio communication system in accordance with the third embodiment is the same as the system in FIG. 2. The block of the radio terminal 12 is the same as the block in FIG. 3, but the function of the control plane level controller 22b is different. The hardware configuration of the radio terminal 12 is the same as the configuration in FIG. 4. The block of the base station 11 is the same as the block in FIG. 5, but the function of the control plane level controller 42b is different. The hardware configuration of the base station 11 is the same as the configuration in FIG. 6.

FIG. 11 is a timing chart of a radio terminal in accordance with a third embodiment. In FIG. 11 the long DRX cycle of FIG. 7 replaced by a DRX cycle. Other parts in FIG. 11 are the same as the parts in FIG. 7, and therefore their explanation is omitted.

The radio terminal 12 acts so that before the event occurs, the DRX cycle is masked, while the measurement is not performed, and the DRX is performed periodically (thick line in Fig. 11). The radio terminal 12 measures and tracks the paging signal during an unmasked DRX cycle.

In the non-masked section, the radio terminal 12 measures at intervals of “DRX / n cycle” (n> 2), as shown in FIG. 11. Consequently, the radio terminal 12 performs filtering measurements at intervals “X” shown in FIG. eleven.

After the occurrence of the event, the radio terminal 12 does not mask the DRX cycle. In other words, the radio terminal 12 measures and tracks the paging signal in each DRX cycle, as shown in FIG. eleven.

FIG. 12 explains a DRX mask pattern. The control plane level controller 22b of the radio terminal 12 resets the DRX mask synchronously with the modification period of the BCCH (Broadcast Control Channel), which is the period of checking for changes in broadcast information.

The bidirectional arrows A11, A12 shown in FIG. 12 indicate the modification period of the BCCH. The control plane level controller 22b resets the DRX mask with timing of the dashed lines A13, A14 shown in FIG. 12. For example, the control plane level controller 22b controls the radio controller 22a to turn on the communication unit 21 (for performing DRX) with timing of the dashed lines A13, A14.

The line with alternating long and short strokes shown in FIG. 12 indicates a period of time during which a DRX cycle mask is reset (a period of time during which DRX is performed). The rectangle and the rectangle with oblique lines shown in FIG. 12 indicate broadcast information (SIB: System Information Block) reported to the radio terminal 12 from the base station 11.

The control plane level controller 22b monitors SIB1 (a rectangle with oblique lines tilted up to the right in FIG. 12) or a paging signal to check if there is a change in the broadcast information. The control plane level controller 22b includes a communication unit 21 for monitoring SIB1 and the paging signal. The control plane level controller 22b performs measurement and tracking of the paging signal using this timing. A rectangle with sloping lines sloping down to the right indicates the SIB whose information has been changed.

The period of time during which the mask is reset can be communicated, for example, using broadcast information, or can be determined in advance. In addition, the time period can be calculated by the device ID of the radio terminal 12. In addition, the radio terminal 12 can easily reset the mask by implementing it.

It was described above that the mask template is synchronized with the BCCH modification period, and now an example of setting another mask template is explained.

Example 1: base station 11 transmits a masking pattern using broadcast information. For example, the base station 11 transmits using broadcast information in which DRX cycle to perform DRX. The control plane level controller 22b of the radio terminal 12 resets the mask within the DRX cycle contained in the received broadcast information, and performs measurement and tracking of the paging signal. The period of time during which the mask is reset may be transmitted, for example, using broadcast information, or may be determined in advance. In addition, the time period can be calculated by the device ID of the radio terminal 12.

Example 2: a masking pattern is reported using a paging signal. For example, when the radio terminal 12 is in standby mode, the base station 11 reports a DRX masking pattern using a paging signal.

Example 3: When the radio terminal 12 is in standby mode, the location is registered in the MME (Mobility Management Node). Location registration is performed at the NAS level and the NAS Attach procedure is performed. The radio terminal 12 receives the masking pattern using the NAS Connect NAS Received message sent and received using the NAS Connect procedure.

Example 4: Each time DRX is masked N times, DRX masking is reset. N can be reported using broadcast information from the base station 11 or can be determined in advance by the base station 11 and the radio terminal 12. In addition, N can be calculated by the device ID of the radio terminal 12.

Example 5: Based on the IMSI (International Mobile Subscriber Identity), which is the identifier of the radio terminal, the radio frame in which the DRX mask is reset is determined. For example, a DRX mask is discarded in a radio frame in which the SFN mod DRX cycle and func (IMSI) become equal to each other, func () is a corresponding function and, for example, a function that outputs an IMSI value.

FIG. 13 is a flowchart of a radio terminal.

(Step S21) The power of the radio terminal 12 is turned on.

(Step S22) The control plane layer controller 22b receives broadcast information from the base station 11.

(Step S23) The control plane layer controller 22b performs the NAS Attach procedure.

(Step S24) The control plane level controller 22b receives the DRX mask pattern. by completing the NAS Attach procedure. The flowchart of FIG. 13 shows an example of processing in the case of Example 3 described above.

(Step S25) The control plane level controller 22b controls the radio controller 22a to perform DRX with the received mask pattern. The radio controller 22a turns the communication unit 21 on and off in accordance with the control of the control plane level controller 22b, whereby a paging signal is measured and monitored. The control plane level controller 22b averages the measured measurements to evaluate their quality.

(Step S26) The controller 22 awaits the event from the application layer.

(Step S27) The controller 22 from the application layer determines whether an event has occurred. In the event that an event has occurred, the controller 22 proceeds from the application layer to step S28. In the case when the event did not occur, the controller 22 from the application layer proceeds to step S26.

(Step S28) The control plane level controller 22b resets all masks. For example, the control plane level controller 22b controls the radio controller 22a so that measurement and tracking of the paging signal is performed in each DRX cycle, as shown after the occurrence of the event in FIG. eleven.

FIG. 14 is a flowchart of a base station.

(Step S31) The control plane level controller 42b notifies the radio terminal 12 of broadcast information through the radio controller 42a.

(Step S32) The control plane layer controller 42b performs the NAS Attach procedure.

(Step S33) The control plane layer controller 42b transmits the DRX mask template using the NAS Attach procedure. The flowchart of FIG. 14 shows an example of processing in the case of Example 3 described above.

(Step S34) The control plane level controller 42b awaits an event report from the radio terminal 12.

(Step S35) The control plane level controller 42b determines whether an event report has been received from the radio terminal 12. In the event that the event report from the radio terminal 12 is received, the control plane level controller 42b completes the processing. In the event that an event report from the radio terminal 12 is not received, the control plane level controller 42b proceeds to step S34.

As described above, the control plane level controller 42b operates such that a period of time during which DRX is not executed is set, and DRX is periodically executed. Then, the control plane level controller 42b and the radio controller 42a filter the measurements at intervals of less than half the DRX cycle length within the DRX cycle of the periodically performed DRX. Due to this, the radio terminal 12 can reduce the increase in the measurement interval and can reduce the deterioration of measurements within the DRX cycle performed periodically DRX to reduce energy consumption.

(Fourth Embodiment)

Next, a fourth embodiment is explained in detail with reference to the drawings. In a fourth embodiment, the base station indicates a DRX to be performed as follows.

The radio communication system in accordance with the fourth embodiment is the same as the system in FIG. 2. The block of the radio terminal 12 is the same as the block in FIG. 3, but the function of the control plane level controller 22b is different. The hardware configuration of the radio terminal 12 is the same as the configuration in FIG. 4. The block of the base station 11 is the same as the block in FIG. 5, but the function of the control plane level controller 42b is different. The hardware configuration of the base station 11 is the same as the configuration in FIG. 6.

FIG. 15 is a timing chart of a radio terminal in accordance with a fourth embodiment. In FIG. 15, the DRX to be performed next is indicated by a paging signal, which is different from FIG. 11. Other parts of FIG. 15 are the same as those in FIG. 11, and therefore their explanation is omitted.

When based in a cell of the base station 11, the control plane level controller 22b of the radio terminal 12 performs measurement and tracking of the search signal. call. The base station 11 indicates, using the paging signal, during which DRX the radio terminal 12 next time measures and tracks the paging signal. The control plane level controller 22b measures and monitors the paging signal during the indicated DRX.

The period of time during which DRX is performed may be indicated by a paging signal or reported using broadcast information. In addition, the time period can be determined in advance or can be calculated by the device ID of the radio terminal 12. In addition, the time period can be determined by the implementation of the radio terminal. For example, base station 11 indicates the start of DRX using broadcast information, and the period of time DRX is determined by the implementation of the radio terminal 12.

Base station 11 may indicate to perform DRX using the NAS. For example, when the radio terminal 12 is in standby mode, the location is recorded in the MME. Location registration is performed at the NAS level and the NAS Attach procedure is performed. Base station 11 indicates the DRX to be performed next using the NAS Connect NAS Received message sent and received using the NAS Connect procedure. The period of time during which DRX is performed can be reported using “NAS Attachment Accepted” or communicated using broadcast information. In addition, the time period may be predetermined or may be determined by the device ID of the radio terminal 12.

FIG. 16 is a flowchart of a radio terminal.

(Step S41) The power of the radio terminal 12 is turned on.

(Step S42) The control plane layer controller 22b receives broadcast information from the base station 11.

(Step S43) The control plane layer controller 22b performs the NAS Attach procedure.

(Step S44) The control plane layer controller 22b receives the DRX, which must be performed next, by a paging signal or by performing the NAS Attach procedure.

(Step S45) The control plane level controller 22b controls the radio controller 22a to perform DRX indicated by the base station 11 (step S44). The control plane level controller 22b performs a DRX measurement and makes an assessment thereof.

(Step S46) The controller 22 from the application layer is in the standby mode of the event.

(Step S47) The controller 22 from the application layer determines whether an event has occurred. In the case when an event has occurred, the controller 22 from the application layer proceeds to step S48. In the case when the event did not occur, the controller 22 from the application layer proceeds to step S4 6.

(Step S48) The control plane level controller 22b performs all DRX. For example, as shown after the occurrence of the event in FIG. 15, the control plane level controller 22b controls the radio controller 22a so that measurement and tracking of the paging signal is performed in each DRX cycle.

FIG. 17 is a flowchart of a base station.

(Step S51) The control plane level controller 42b notifies the radio terminal 12 of broadcast information through the radio controller 42a.

(Step S52) The control plane layer controller 42b performs the NAS Attach procedure.

(Step S53) The control plane level controller 42b transmits the DRX, which is to be performed next, by the paging signal or by performing the NAS Attach procedure.

(Step S54) The control plane level controller 42b is in the standby mode of the event report from the radio terminal 12.

(Step S55) The control plane level controller 42b determines whether an event report has been received from the radio terminal 12. If an event report from the radio terminal 12 is received, the control plane level controller 42b completes the processing. If an event report from the radio terminal 12 is not received, the control plane level controller 42b proceeds to step S54.

As described above, the control plane level controller 42b receives the DRX, which must be executed next, using a paging signal or NAS. Then, the control plane level controller 42b and the radio controller 42a filter the measurements at intervals of less than half the DRX cycle length during the DRX cycle, which will be performed as follows. Due to this, the radio terminal 12 can reduce the deterioration of measurement, as well as reduce energy consumption.

(Fifth Embodiment)

Next, a fifth embodiment is explained in detail with reference to the drawings. In the fifth embodiment, two DRX cycles are set and paging signal measurement and tracking are performed.

The radio communication system in accordance with the fifth embodiment is the same as the system in FIG. 2. The block of the radio terminal 12 is the same as the block in FIG. 3, but the function of the control plane level controller 22b is different. The hardware configuration of the radio terminal 12 is the same as the configuration in FIG. 4. The block of the base station 11 is the same as the block in FIG. 5, but the function of the control plane level controller 42b is different. The hardware configuration of the base station 11 is the same as the configuration in FIG. 6.

FIG. 18 is a timing chart of a radio terminal in accordance with a fifth embodiment. FIG. 18 shows a short DRX cycle and a long DRX cycle, the period of which is longer than the short DRX cycle duration. The short DRX cycle, for example, is a traditional DRX cycle, and the long DRX cycle is made longer in the cycle than the short DRX cycle in order to reduce the power consumption of the radio terminal 12.

The radio terminal 12 performs DRX in a short DRX cycle, for example, for a predetermined period of time and then performs DRX in a long DRX cycle for a predetermined period of time. Then, the radio terminal 12 repeats these operations. A period of time during which DRX is performed in a short DRX cycle and a period of time during which DRX is performed in a long DRX cycle are reported, for example, using broadcast information.

If the DRX cycle is extended in a simple manner, the time interval during which the measurement is performed is also lengthened, and therefore, the control plane level controller 22b of the radio terminal 12 measures for the long DRX at least once with traditional DRX intervals. Therefore, it is possible to measure many times during the DRX time span. However, the measurement is performed at intervals of "long DRX / n cycle" (n> 2). Therefore, the radio terminal 12 performs control to perform filtering of the measurement at least with an interval “X”, as shown in FIG. 18. The control plane level controller 22b may perform the measurement as is conventional in a short DRX cycle, but to improve measurement accuracy, it filters the measurement at least with a “short DRX / 2 cycle” interval.

The radio terminal 12 averages two measurements to calculate the measured measurement value. For example, the radio terminal 12 filters two measurement values m on the left side and m on the right side in the long DRX cycle shown in FIG. eighteen.

As an example of modification, if the DRX cycle is extended in a simple manner, it is obvious that the time interval during which the measurement is performed is lengthened, and therefore there is also a method in which the measurement and tracking of the paging signal are not performed at all in the long DRX cycle.

In the aforementioned period of time during which DRX is performed in a short DRX cycle and a period of time during which DRX is performed in a long DRX cycle, are reported using broadcast information, and another example is explained here.

Example 1: When the radio terminal 12 is in standby mode, the base station 11 reports a period of time during which DRX is performed using a paging signal.

Example 2: When the radio terminal 12 is in standby mode, the location is recorded in the MME. Location registration is performed at the NAS level and the NAS Attach procedure is performed. The radio terminal 12 receives a period of time during which the DRX is performed using the NAS Attaching NAS Accepted message sent and received using the NAS Attach procedure.

Example 3: The control plane level controller 22b performs DRX in a short DRX cycle N times, and then performs DRX in a long DRX cycle M times. The values of N and M may be reported using broadcast information, or predetermined values may be used. In addition, the control plane level controller 22b may calculate the values of N and M from the device ID of the radio terminal 12.

Example 4: The control plane level controller 22b switches DRX cycles in conjunction with the BCCH modification period explained in FIG. 12. For example, the control plane level controller 22b performs DRX in a short DRX cycle every N modification boundaries (dashed lines A13, A14 in FIG. 12). The period of time during which DRX is performed in a short DRX cycle can be reported, for example, using broadcast information, or a value determined in advance can be used. In addition, the control plane level controller 22b may calculate a period of time during which DRX is performed in a short DRX cycle from the device ID of the radio terminal 12.

Example 5: The control plane level controller 22b starts DRX in a short DRX cycle in a radio frame in which the SFN mod DRX cycle and func (IMSI) become equal to each other. The control plane level controller 22b performs DRX in a short DRX cycle in N consecutive radio frames. N may be communicated, for example, using broadcast information, or a value determined in advance may be used. In addition, the control plane level controller 22b can calculate N from the device ID of the radio terminal 12. When completing DRX in a short DRX cycle, the control plane level controller 22b performs DRX in a long DRX cycle.

FIG. 19 is a flowchart of a radio terminal.

(Step S61) The power of the radio terminal 12 is turned on.

(Step S62) The control plane layer controller 22b receives broadcast information from the base station 11.

(Step S63) The control plane layer controller 22b performs the NAS Attach procedure.

(Step S64) The control plane layer controller 22b obtains a period of time during which DRX is performed in a short DRX cycle and a period of time during which DRX is performed in a long DRX cycle, for example, using “NAS Attachment Accepted”. The control plane layer controller 22b may also obtain a period of time during which DRX is performed in a short DRX cycle and a period of time during which DRX is performed in a long DRX cycle from broadcast information.

(Step S65) The control plane level controller 22b controls the radio controller 22a to perform DRX in the short DRX cycle and in the long DRX cycle indicated by the base station 11 (step S64). The control plane level controller 22b performs a DRX measurement and makes an assessment thereof.

FIG. 20 is a flowchart of a base station.

(Step S71) The control plane level controller 42b notifies the radio terminal 12 of broadcast information through the radio controller 42a.

(Step S72) The control plane layer controller 42b performs the NAS Attach procedure.

(Step S73) The control plane layer controller 42b transmits a period of time during which DRX in the short DRX cycle and DRX in the long DRX cycle are executed, for example, by using broadcast information or by performing the NAS Attach procedure.

As described above, the control plane level controller 42b performs DRX in a short DRX cycle and in a long DRX cycle. Due to this, the radio terminal 12. can improve the measurement accuracy with a short DRX cycle, as well as reduce energy consumption with a long DRX cycle.

(Sixth Embodiment)

Next, a sixth embodiment is explained in detail with reference to the drawings. In the sixth embodiment, after turning on the power of the radio terminal 12, the NAS Attach procedure and the NAS Detach procedure are performed. After that, the radio terminal 12 turns off the power of the communication unit 21. After that, if an event is detected in the application layer, the radio terminal 12 measures and tracks the paging signal using DRX and, for example, transmits event information to the base station 11 using UL.

The radio communication system in accordance with the sixth embodiment is the same as the system in FIG. 2. The block of the radio terminal 12 is the same as the block in FIG. 3, but the function of the control plane level controller 22b is different. The hardware configuration of the radio terminal 12 is the same as the configuration in FIG. 4. The block of the base station 11 is the same as the block in FIG. 5, but the function of the control plane level controller 42b is different. The hardware configuration of the base station 11 is the same as the configuration in FIG. 6.

FIG. 21 is a timing chart of a radio terminal in accordance with a sixth embodiment. The arrow A21 in FIG. 21 indicates the completion of the NAS Attach procedure, and the arrow A22 indicates the completion of the NAS Detach procedure. When the power is turned on, the radio terminal 12 searches for the cell and registers the location by performing the NAS Attach procedure, as indicated by arrow A21. Then, the radio terminal 12 turns off the power of the communication unit 21 by performing the NAS Disconnect procedure, as indicated by arrow A22.

When an event that occurs in the application layer is detected, the application layer controller 22c of the radio terminal 12 notifies the controller of the control plane level 22b of the detection. The control plane level controller 22b controls the radio controller 22a to turn on the communication unit 21.

The control plane level controller 22b registers the location by performing the NAS Attach procedure, as indicated by arrow A23. The control plane level controller 22b performs DRX in a short DRX cycle to measure and track the paging signal.

The control plane level controller 22b transmits the event information of the base station 11 as UL data and performs the NAS Disconnect procedure, as indicated by arrow A24. Then, the control plane level controller 22b turns off the power of the communication unit 21.

After that, when an event is detected by the application layer controller 22c, the control plane layer controller 22b performs the same operation as described above.

FIG. 22 explains the operations of the NAS Attach procedure and the NAS Detach procedure.

(Step S81) The control plane level controller 22b of the radio terminal 12 transmits a “NAS Attach Request” to the base station 11.

(Step S82) The control plane level controller 42b of the base station 11 transmits. “Attach NAS Accepted” to Radio 12.

(Step S83) The control plane level controller 22b of the radio terminal 12 transmits a “NAS Connection Complete” to the base station 11.

(Step S84) The control plane level controller 22b of the radio terminal 12 transmits a “NAS Disconnect Request” to the base station 11.

(Step S85) The control plane level controller 42b of the base station 11 transmits a "NAS Disconnect Received" to the radio terminal 12.

23 is a flowchart of a radio terminal.

(Step S91) The power of the radio terminal 12 is turned on.

(Step S92) The control plane layer controller 22b performs the NAS Attach procedure and the NAS Detach procedure. For example, the control plane level controller 22b performs what is indicated by arrow A21 and what is indicated by arrow A22 shown in FIG. 21.

(Step S93) The application layer controller 22c waits for an event.

(Step S94) The application layer controller 22c determines whether an event has occurred. In the event that an event has occurred, the application layer controller 22c proceeds to step S95. In the event that an event has not occurred, the application layer controller 22c proceeds to step S93.

(Step S95) The radio controller 22a includes a communication unit 21 in accordance with the control of the control plane level controller 22b.

(Step S96) The control plane level controller 22b causes DRX execution.

(Step S97) The control plane layer controller 22b performs the NAS Attach procedure.

(Step S98) The communication unit 21 transmits the event information on the UL to the base station 11.

(Step S99) The control plane layer controller 22b performs the NAS Disconnect procedure.

FIG. 24 is a flowchart of a base station.

(Step S101) The control plane layer controller 42b performs the NAS Attach procedure.

(Step S102) The control plane level controller 42b communicates with the radio terminal 12 through the radio controller 42a and the communication unit 41.

(Step S103) The control plane layer controller 42b performs the NAS Disconnect procedure. The above processing is the same before and after the event.

As described above, the control plane level controller 42b controls the radio controller 22a to perform DRX in conjunction with the event detection by the application layer controller 22c. Due to this, the radio terminal 12 can reduce energy consumption before the event occurs.

The above only illustrates the principles of the invention. In addition, a person skilled in the art can make various modifications and changes, and the present invention is not limited to the exact configurations and application examples shown and explained above, and it is believed that all relevant examples of modifications and their equivalents are within the scope of the present invention in accordance with the attached the claims and its equivalents.

LIST OF CONVENTIONS

one radio terminal 1a communication unit 1b controller

Claims (21)

1. A radio terminal that communicates with a base station, comprising: a communication unit configured to perform radio measurements and tracking the paging signal of the base station; and a control unit configured to control the communication unit so as to configure a first time slice and a second time slice, receive information related to the first time slice and the second time slice using a No Access Level (NAS) message from the base station, and execute radio measurements and tracking during the first time interval, but not to perform radio measurements and tracking during the second time interval after the first time interval, while the control unit is further configured to control so as to resume radio measurements and tracking by completing the second time slot to transmit uplink data that is created by the radio terminal during the second time slot. 2. The radio terminal according to claim 1, in which time periods are communicated in order to execute the first time span and the second time span using the “No Access Layer Admission (NAS) Accepted”. 3. A radio communication system comprising: radio terminal and a base station that communicates with the radio terminal, while The radio terminal includes: a communication unit configured to perform radio measurements and tracking the paging signal of the base station; and a control unit configured to control the communication unit so as to configure the first time slice and second time slice, receive information related to the first time slice and the second time slice using the Access Level (NAS) message from the base station, and perform radio measurements and tracking during the first time interval, but do not perform radio measurements and tracking during the second time interval after the first time interval, while the control unit is further configured to control so as to resume radio measurements and tracking by completing the second time interval in order to transmit uplink data that is created by the radio terminal during the second time interval. 4. A radio base station that communicates with a radio terminal that configures a first time span and a second time span following a first time span, the base station comprising: a communication unit, configured to transmit information that relates to the first time interval and the second time interval, using the message Level without access (NAS) in the radio terminal, while the first time span is the time span in which the radio terminal controls communication so as to perform radio measurements and tracking the paging signal of the base station, and the second time span is the time span in which the radio terminal controls communication so as not to perform radio measurements and tracking the length of time must be completed so that the radio terminal can resume radio measurements and tracking in order to transmit uplink data that is created for the terminal during the second time interval. 5. A radio communication method for a radio terminal that communicates with a base station, comprising the steps of: performing radio measurements and tracking of the paging signal of the base station; configure the first time span and the second time span, receive information regarding the first time span and the second time span using the Access Level (NAS) message from the base station, and perform measurements and tracking during the first time span, but do not perform radio measurements and tracking during the second time interval after the first time interval; and further controlled so as to resume radio measurements and tracking by completing the second time span in order to transmit uplink data that is created by the radio terminal during the second time span.

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