KR101841693B1 - Apparatus and method for controling in-device coexistence interfe|rence in wireless communication system - Google Patents

Abstract

A method for controlling intra-device interference by a terminal in a wireless communication system is disclosed. The method includes receiving, from a base station, coexistence interference control measurement setting information in a device including a condition triggering a control operation of coexistence interference in the device, measuring the coexistence interference in the device, A coexistence interference indicator in the device indicating whether coexistence interference in the device is in progress, a step of transmitting the measurement result to the base station, and a coexistence interference control operation in the device From the base station. According to the present invention, it is possible to control so as to prevent coexistence interference in the device in the wireless network.

Description

[0001] APPARATUS AND METHOD FOR CONTROLLING IN-DEVICE COEXISTENCE INTERFACE [0002] < [lambda] > RENCE IN WIRELESS COMMUNICATION SYSTEM &

The present invention relates to a wireless communication system, and more particularly, to an apparatus and method for controlling coexistence interference in a wireless communication system.

Wireless communication systems typically use one bandwidth for data transmission. For example, a second-generation wireless communication system uses a bandwidth of 200 KHz to 1.25 MHz, and a third-generation wireless communication system uses a bandwidth of 5 MHz to 10 MHz. To support increasing transmission capacity, the latest 3GPP (Long Term Evolution) or IEEE 802.16m (3GPP) continues to extend its bandwidth to 20 MHz or more. Increasing the bandwidth to increase the transmission capacity is essential, but supporting large bandwidths even at low levels of required services can result in large power consumption.

Accordingly, a multi-component carrier system has emerged in which a carrier having a bandwidth and a center frequency is defined and data can be transmitted and / or received over a plurality of carriers in a wide band. By using one or more carriers, it is possible to support narrowband and broadband at the same time. For example, if one carrier corresponds to a bandwidth of 5 MHz, it can support a maximum bandwidth of 20 MHz by using four carriers.

With today's ubiquitous access networks, users can connect to different networks in different geographical areas and maintain connectivity anywhere. In a conventional manner in which one terminal performs communication with one network system, the user carries different devices supporting each network system. However, in recent years, as the functions of a single terminal have become more sophisticated and complex, it has become possible to simultaneously perform communication with a plurality of network systems even with a single terminal, and convenience of users is increasing.

However, if one terminal simultaneously communicates on a plurality of network system bands, in-device coexistence interference (IDC) may occur. Coexistence interference in a device refers to interference when transmission in one frequency band in the same terminal causes interference in reception in another frequency band. For example, in-device coexistence interference may occur between a Bluetooth system band and an 802.16 system band when one terminal simultaneously supports a bluetooth system and an 802.16 system. Coexistence interference in a device may occur mainly when the spacing of the frequency band boundaries of a heterogeneous network system is not sufficiently wide.

Various in-device coexistence interference avoidance (ICO) techniques have been proposed.

An object of the present invention is to provide an apparatus and method for controlling coexistence interference in a device.

It is another object of the present invention to provide an apparatus and method for transmitting information for controlling coexistence interference in a device.

It is another object of the present invention to provide an apparatus and a method for triggering a control operation of coexistence interference in a device.

According to an aspect of the present invention, there is provided a method of controlling intra-device coexistence interference by a terminal in a wireless communication system, the method comprising: receiving, from a base station, coexistence interference control measurement setting information including conditions for triggering a control operation of intra- Determining whether coexistence interference in the device is in progress, performing measurement without considering the coexistence interference in the device, and determining whether coexistence interference in the device is in progress, Transmitting the coexistence interference indicator and the measurement result to the base station, and receiving the coexistence interference control operation from the base station.

The device coexistence interference control measurement setup information may be triggered by an event indicating that the coexistence interference progression at the corresponding frequency starts when the measurement result considering the coexistence interference in the device becomes larger than the entry threshold value, And transmitting the coexistence interference indicator and the measurement result to the base station based on the entry threshold value.

The coexistence interference control measurement setting information of the device is a measurement that does not take into consideration the coexistence interference in the device and the coexistence interference in the device for the frequency band which is difficult to use due to the coexistence interference in the device, Further comprising an elimination threshold value for instructing to trigger an event indicating that the frequency band which is determined to be difficult to use due to coexistence interference in the device is reusable if the difference value of the result falls below the elimination threshold value, The coexistence interference indicator in the device and the measurement result can be transmitted to the base station.

The measurement result may further include an unusable frequency indicating that intra-device coexistence interference is in progress in the frequency band.

The device coexistence interference control measurement setup information may be received from the base station through an RRC (Radio Resource Control) connection reestablishment message.

The device coexistence interference control measurement setting information can be received from the base station through a system information block.

According to another aspect of the present invention, there is provided a method for controlling intra-device coexistence interference by a base station in a wireless communication system, the method comprising: transmitting intra-device coexistence interference control measurement setting information including conditions for triggering a control operation of intra- An in-device coexistence interference indicator for indicating whether coexistence interference in the device is in progress, and receiving the measurement result from the terminal; determining an intra-device coexistence interference control operation based on the measurement result; And transmitting the coexistence interference control operation in the device to the terminal.

The device coexistence interference control measurement setup information includes an event indicating that the coexistence interference progression at the corresponding frequency starts when the measurement result considering the coexistence interference in the device becomes larger than the entry threshold value, And may further include the entry threshold value for instructing triggering.

The coexistence interference control measurement setting information of the device is a measurement that does not take into consideration the coexistence interference in the device and the coexistence interference in the device for the frequency band which is difficult to use due to the coexistence interference in the device, And a threshold value for instructing to trigger an event indicating that the frequency band that is determined to be difficult to use due to coexistence interference in the device can be reused if the difference value of the result falls below the resolution threshold.

The measurement result may further include an unusable frequency indicating that intra-device coexistence interference is in progress in the frequency band.

The coexistence interference control measurement setup information may be transmitted to the UE through an RRC (Radio Resource Control) connection reestablishment message.

The coexistence interference control measurement setting information may be transmitted to the terminal through a system information block.

According to the present invention, it is possible to control so as to prevent coexistence interference in the device in the wireless network. Concretely, it is possible to properly trigger the operation to control coexistence interference in the apparatus so as not to perform too often or too little, and to select and perform an appropriate coexistence interference control operation in accordance with the triggering situation.

1 illustrates a wireless communication system to which embodiments of the present invention are applied.
2 is an explanatory diagram for explaining co-existence interference in a device.
Figure 3 is an example of intra-device coexistence interference from an ISM transmitter to an LTE receiver.
4 is an example in which the ISM band and the LTE band are divided on the frequency band.
5 is an explanatory diagram showing an example of mitigating coexistence interference in an apparatus using the FDM scheme applied to the present invention.
6 is an explanatory diagram showing another example of mitigating coexistence interference in an apparatus using the FDM scheme applied to the present invention.
7 and 8 are explanatory diagrams showing an example of mitigating coexistence interference in a device using a power control (PC) scheme applied to the present invention.
FIG. 9 is an explanatory diagram showing an example of mitigating coexistence interference in a device using the TDM scheme applied to the present invention.
10 shows transmission and reception timings on the time axis of the LTE band and the ISM band using the TDM scheme according to the present invention.
11 is a diagram showing another example of mitigating coexistence interference in a device using the TDM scheme according to the present invention.
12 is a view showing another example of mitigating coexistence interference in a device using the TDM scheme applied to the present invention.
13 is a diagram showing another example of mitigating coexistence interference in a device using the TDM scheme applied to the present invention.
Fig. 14 (Figs. 14A and 14B) is a flowchart showing an example of operation of a terminal and a base station performing intra-device coexistence interference control.
FIG. 15 (FIGS. 15A and 15B) is a flowchart showing another example of operation of a terminal and a base station that perform intra-device coexistence interference control.
16 is a case in which the terminal receives an interference signal in the device.
FIG. 17 is an explanatory view for explaining measurement rules for obtaining measurement samples in an interference weak band applied to the present invention; FIG.
18 is an explanatory view for explaining a measurement rule for obtaining measurement samples in the interference flaw band according to another example of the present invention.

Hereinafter, some embodiments will be described in detail with reference to exemplary drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present disclosure rather unclear.

In describing the components of the present specification, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, Quot; may be "connected," "coupled," or "connected. &Quot;

In addition, the present invention will be described with respect to a wireless communication network. The work performed in the wireless communication network may be performed in a process of controlling a network and transmitting data by a system (e.g., a base station) Work can be done at a terminal connected to the network.

1 illustrates a wireless communication system to which embodiments of the present invention are applied.

1, a wireless communication system is widely deployed to provide various communication services such as voice, packet data, etc., and includes a user equipment (UE) 10, an evolved NodeB (eNB) 20, (Wireless LAN Access Point) 30, and a GPS (Global Positioning System) 40 satellite. Here, the wireless LAN is a device supporting IEEE 802.11 technology, which is a wireless standard, and IEEE 802.11 can be mixed with a WiFi system.

The terminal 10 may be located within a coverage of a plurality of networks such as a cellular network, a wireless LAN, a broadcast network, a satellite system, and the like. In order for the terminal 10 to access various networks and various services regardless of time and place, the terminal 10 recently has a plurality of wireless transceivers. For example, a smart phone includes Long Term Evolution (LTE), WiFi, a Bluetooth transceiver, and a GPS receiver. The design of the terminal 10 is becoming more complex in order to integrate more transceivers in one same terminal 10 while maintaining good performance. This may increase the likelihood of in-device coexistence interference (IDC).

Hereinafter, downlink (DL) means communication from the base station 20 to the terminal 10, and uplink (UL) means communication from the terminal 10 to the base station 20. In the downlink, the transmitter may be part of the base station 20 and the receiver may be part of the terminal 10. Also, in the uplink, the transmitter may be part of the terminal 10 and the receiver may be part of the base station 20.

The terminal 10 may be fixed or mobile and may be referred to by other terms such as a Mobile Station (MS), a User Terminal (UT), a Subscriber Station (SS), a Mobile Terminal (MT) . The base station 20 is a fixed station that communicates with the terminal 10 and includes a base station (BS), a base transceiver system (BTS), an access point, a femto base station (Femto BS) (relay).

There are no restrictions on multiple access schemes applied to wireless communication systems. (CDMA), Time Division Multiple Access (TDMA), Frequency Division Multiple Access (FDMA), Orthogonal Frequency Division Multiple Access (OFDMA), Single Carrier-FDMA , OFDM-CDMA, and the like. A TDD (Time Division Duplex) scheme in which uplink and downlink transmissions are transmitted using different time periods, or an FDD (Frequency Division Duplex) scheme in which they are transmitted using different frequencies can be used.

2 is an explanatory diagram for explaining co-existence interference in a device.

Referring to FIG. 2, the terminal 20 includes an LTE RF 21, a GPS RF 22, and a Bluetooth / WiFi RF 23. Transmission / reception antennas 24, 25 and 26 are connected to each RF. That is, various kinds of RFs are closely mounted in one device platform. Here, the transmission power of one RF may be much larger than the reception power level of another RF receiver. At this time, if the frequency spacing between RFs is not sufficient and the filtering technique is not supported, any RF transmit signal may cause significant interference to other RF receivers in the device. For example, (1) is an example in which the transmission signal of the LTE RF 21 causes intra-device coexistence interference with the GPS RF 22 and the Bluetooth / WiFi RF 23, (2) 23 cause coexistence interference in the apparatus with respect to the LTE RF 21.

Figure 3 is an example of co-existing interference in an instrument from an industrial, scientific and medical (ISM) transmitter to an LTE receiver. The ISM band represents a band that can be freely used without permission in the industrial science and medical field.

Referring to FIG. 3, it can be seen that the band of the signal received at the LTE receiver overlaps the band of the transmitted signal of the ISM transmitter. In this case, coexistence interference in the equipment may occur.

4 is an example in which the ISM band and the LTE band are divided on the frequency band.

Referring to FIG. 4, band 40, band 7, and band 38 are LTE bands. Band 40 occupies the 2300 to 2400 MHz band in the TDD mode and Band 7 occupies the 2500 to 2570 MHz band as the uplink in the FDD mode. And the band 38 occupies the 2570 to 2620 MHz band in the TDD mode. Meanwhile, the ISM band is used as a Wi-Fi channel and a Bluetooth channel, and occupies 2400 to 2483.5 MHz. Here, the situation where coexistence interference occurs in the device is shown in Table 1 below.

Interference band Type of interference Band 40 ISM Tx -> LTE TDD DL Rx Band 40 LTE TDD UL Tx -> ISM Rx Band 7 LTE FDD UL Tx -> ISM Rx Band 7/13/14 LTE FDD UL Tx -> GPS Rx

Referring to Table 1, the notation 'a-> b' in the form of interference indicates a situation in which transmitter a causes co-existence interference in the apparatus with receiver b. Thus, in band 40, the ISM transmitter causes intra-device coexistence interference to the downlink TDD receiver (LTE DL TDD Rx) of the LTE band. A filtering scheme can mitigate co-existence interference in the device to some extent, but is not sufficient. In addition to the filtering method, applying the FDM (Frequency Division Multiplex) scheme can more effectively mitigate coexistence interference in the device.

5 is an explanatory diagram showing an example of mitigating coexistence interference in an apparatus using the FDM scheme applied to the present invention.

Referring to FIG. 5, the LTE band can be shifted so that the LTE band does not overlap with the ISM band. This results in a handover of the terminal from the ISM band. However, this requires a legacy measurement or a new signaling to accurately trigger the mobility procedure or the radio link failure (RLF) procedure. Alternatively, there may be a way to avoid the problematic parts in the LTE band through filtering or resource allocation techniques. Or in the case where LTE carrier aggregation is used, overlap interference may be avoided through a procedure of reconfiguring the set of used carriers.

6 is an explanatory diagram showing another example of mitigating coexistence interference in an apparatus using the FDM scheme applied to the present invention.

Referring to FIG. 6, the ISM band may be reduced and moved away from the LTE band. However, backward compatibility problems may occur in this manner. In the case of Bluetooth, the backward compatibility problem can be solved to some extent by the adaptive frequency hopping mechanism, but in the case of Wi-Fi, it may be difficult to solve the backward compatibility problem.

7 and 8 are explanatory diagrams showing an example of mitigating coexistence interference in a device using a power control (PC) scheme applied to the present invention.

Referring to FIG. 7, the UE can reduce the transmission power of the LTE signal to a certain level, thereby avoiding intra-device coexistence interference, and improve the reception quality of the ISM band. Referring to FIG. 8, It is possible to improve the reception quality of the LTE signal by avoiding coexistence interference in the apparatus.

9 is an explanatory diagram showing an example of mitigating coexistence interference in a device by using a TDM (Time Division Multiplex) scheme applied to the present invention.

Referring to FIG. 9, if the reception time of the LTE signal is not overlapped with the transmission time in the ISM band, coexistence interference in the device can be avoided. For example, if a signal in the ISM band is transmitted at t ₀ , an LTE signal is received at t ₁ .

As described above, the transmission / reception timing in the time domain of the LTE band and the ISM band using the TDM scheme according to the present invention can be expressed as shown in FIG.

Referring to FIG. 10, it can be seen that intra-device coexistence interference can be avoided without movement between the LTE band and the ISM band by the method shown in FIG.

11 is a diagram showing another example of mitigating coexistence interference in a device using the TDM scheme according to the present invention.

Referring to FIG. 11, a TDM scheme based on Discontinuous Reception (DRX) is used in which a predetermined pattern periodicity period is divided into a scheduled period and an unscheduled period period It is possible to avoid coexistence interference in the apparatus.

Avoids transmission of LTE within an unscheduled periodic interval to avoid mutual interference between LTE and ISM. However, LTE primary transmissions such as Random Access and Hybrid Automatic Repeat reQuest (HARQ) retransmission may be allowed even within a scheduled period.

Avoid transmission of ISMs within a scheduled period and allow transmission of LTE to avoid mutual interference between LTE and ISM. Like the unscheduled periodic interval, an ISM primary transmission such as a beacon or Wi-Fi may be allowed within the scheduled periodic interval. LTE transmissions may be prevented to protect such ISM primary transmissions. Special signaling for major ISM transport protections such as beacons can be added. For example, information on a period of beacon signaling and information on a subframe offset may be added. At this time, the subframe offset number and the system frame number can be set to 0 as a reference. The system frame number is a value that can have one of 0 to 1023 in units of a radio frame in the LTE system. One radio frame is composed of 10 subframes. Knowing the subframe offset number and the system frame number can determine the exact frame position in the system.

12 is a view showing another example of mitigating coexistence interference in a device using the TDM scheme applied to the present invention.

Referring to FIG. 12, it is preferable that a retransmission signal is protected when data is transmitted based on HARQ as a HARQ-based TDM scheme. Here, protection means that retransmission must be done. If retransmissions are not made to mitigate or avoid coexistence in the TDM scheme, the performance of the system will be significantly degraded. Based on this point, the transmission pattern is determined by considering the retransmission period. For DL transmission, 1 and 6 subframes are reserved in advance and 2 and 7 subframes are reserved for UL transmission. This is called scheduled subframes. In order to mitigate coexistence interference in the device, unscheduled subframes will not be used for transmission for protection of ISM bands.

Similar to the DRX-based scheme, in the HARQ-based scheme, subframes reserved for transmission may be prevented from being transmitted for critical signal transmission in the ISM. Conversely, even in non-scheduled subframes, transmission of important messages such as random access, system information, and paging signals may be allowed.

This pattern can be given as a bitmap pattern. That is, the number of server frames represented by one bit may be one or more. The period of the pattern is (the total length of the bitmap × the number of subframes per bit), and each bit can have a value of 0 if the subframe indicated by the bit is a scheduled subframe or a value of 1 if it is a non-scheduled subframe . Conversely, it may be set to 1 if each subframe is a scheduled subframe or to have a value of 0 if it is a non-scheduled subframe.

For example, assume that the period is 20, the pattern representing the subframe is 1001001000, the unscheduled subframe has a value of 0, and the number of subframes represented by one bit is two. Since the first, fourth, and seventh bits in the pattern indicating the subframe have a value of 1, it can be seen that the subframes 0, 1, 6, 7, 12, and 13 are the scheduled subframes in each period.

13 is a diagram showing another example of mitigating coexistence interference in a device using the TDM scheme applied to the present invention.

Referring to FIG. 13, in an autonomous denial scheme using a TDM scheme, when coexistence in the UE occurs in the UE, the LTE rejects the transmission to protect the ISM reception. Here, the checked portion means that transmission or reception is approved, and the portion marked with X (X) means that transmission or reception is rejected. Even if the UL transmission is granted from the base station, the terminal rejects the allocation to protect the ISM reception and does not perform the UL transmission. Similarly, the ISM case rejects transmissions to protect LTE reception.

Now, a method for controlling coexistence interference in a device according to the present invention will be described.

Fig. 14 (Figs. 14A and 14B) is a flowchart showing an example of the operations of a terminal and a base station that perform intra-device coexistence interference control. Relates to an initial setting operation of a terminal, and relates to an operation of transmitting terminal capability information.

Referring to FIG. 14, the UE transmits performance information (UE capability) of the UE to the BS (S1400). The performance information of the UE may include information on whether there is an IDC possibly exists in the device. In addition, it may include information on a frequency band in which coexistence interference in the device may exist. It may also include information on frequency bands that are not likely to have coexistence interference in the device. Alternatively, it may include information on the frequency bands in which coexistence in the device is present, although it is not likely to be present in the device.

Here, a frequency band in which coexistence interference may exist is a frequency band that may be an unusuable frequency, and an unusable frequency is an on-going IDC in the corresponding frequency. It means that communication at frequency is not easy.

The following table shows scenarios for whether coexistence in the device is underway.

scenario Justice One Co-existence interference in the equipment in the serving frequency band 2 In the presence of potential coexistence interference in the serving frequency band (not coexistent interference currently in the device) 3 Coexistence interference in the equipment is in progress in the frequency band other than the serving frequency band 4 Potential coexistence interference in a frequency band that is not a serving frequency band (non-coexistent interference currently in progress)

Each scenario indicates an interference condition based on the type of interference and the frequency band. Since the unusable frequency band is independent of whether it is the serving frequency band, both Scenario 1 and Scenario 3 are considered to be under coexistence in the device.

16 is for a case in which the terminal receives an interference signal in the device.

Referring to FIG. 16, it can be classified into seven cases based on the frequency and strength of interference.

If the above seven cases are classified into four patterns based on the frequency of interference, case 1 and case 2 are continuous, case 3 and case 4 are burtsy, cases 5 and 6 are dull sparse, and case 7 can be classified into a pattern of none.

Case 1, Case 3 and Case 5 are very strong, Case 2, Case 4 and Case 6 are weak enough, Case 7 can be classified into a pattern of none.

Here, Case 1 and Case 3 are cases where it is determined in the present invention that coexistence interference in the device is in progress. At least the interference is continuous or frequent, and the intensity is very strong.

On the other hand, a state in which the coexistence interference occurs but the coexistence interference in the device is likely to change to the state in which the coexistence interference is in progress is referred to as "presence of coexistence interference in the device" For example, Case 2, Case 4, Case 5, and Case 6 may determine that there is a potential coexistence in the device. As another example, it can be determined that coexistence interference in a potential device exists only in case 5, where the intensity is very strong.

Meanwhile, the capability information of the UE transmitted in step S1400 may include an IDC support indication indicating whether the UE has an IDC capability to control intra-device coexistence interference.

The performance information of the UE may include a value recommended by the UE among the threshold values (entry threshold value, resolution threshold value, ICO-MPR_in, or ICO-MPR_out) as a criterion for determining whether coexistence interference in the device is in progress. The threshold values may be set differently for each UE based on the characteristics of the UE, and a threshold value recommended by each UE may be included in the UE performance information. The thresholds may be different for each frequency band or may be the same for all frequency bands. Threshold values serving as criteria for determining whether coexistence interference in the device is in progress will be described in detail below.

In addition, information indicating the ISM performance of the terminal may be included. As an example of the ISM performance of the UE, the maximum transmission power of the LTE uplink transmission may be reduced in order to reduce interference to the ISM. The reduction of the maximum transmission value will depend on the ISM performance of the UE.

In step S1400, the capability information of the terminal transmitted by the terminal may be included in the terminal capability information message, and the terminal capability information message may include a physical layer parameter information entity or a measurement parameter And may include a Measurement Parameters Information Entity. The physical layer parameter information entity may include information indicating whether or not the coexistence interference control operation is performed in the apparatus. This indicates whether or not the terminal supports the coexistence interference in the device with or without the control operation.

In addition, the measurement parameter information entity may include frequency band information. Here, the measurement parameter information entity may be configured in the form of a list of frequency bands having coexistence interference possibility. The frequency band information included in the measurement parameter information entity may include a threshold value (entry threshold value, resolution threshold value, ICO-MPR_in or ICO-MPR_out) as a criterion for determining whether coexistence interference in the device is in progress, But may also include information about potential IDC frequency bands in the device.

The threshold value (entry threshold value, resolution threshold value, ICO-MPR_in or ICO-MPR_out) serving as a criterion for determining whether the coexistence interference in the device is in progress is present for each frequency band in the frequency band list in which there is a possibility of co- . In addition, a threshold value (entry threshold value, resolution threshold value, ICO-MPR_in or ICO-MPR_out) serving as a criterion for determining whether the coexistence interference in the device is in progress may be determined based on all frequencies in the frequency band list The same applies to the bands.

The base station transmits in-device coexistence interference avoidance measurement configuration (hereinafter referred to as ICO measurement setting information) including conditions for triggering a control operation of intra-device coexistence interference to the terminal (S 1405) . The ICO measurement setup information may be included in an RRC connection reconfiguration message.

The ICO measurement setup information includes IDC entry threshold information, and the measurement result considering the coexistence interference in the device is compared with the measurement result not considering the coexistence interference in the device, and the coexistence interference in the device It can be determined that the coexistence interference in the device is on-going IDC if the measurement result considering the coexistence interference in the device exceeds the coexistence interference threshold value in the device. The coexistence interference in the device can be transmitted in the form of an unusable frequency.

Also, the ICO measurement setting information includes IDC release threshold information. In case of coexistence interference in the device, the difference between the measurement result considering the coexistence interference in the device and the measurement result not considering the coexistence interference in the device for the frequency band which is difficult to use due to the coexistence interference in the device, If it falls below the resolution threshold, it can be judged that the frequency band that it has determined to be difficult to use due to coexistence interference in the device can be used again. The coexistence interference cancellation threshold value of the device can be set to the same value as the coexistence interference entry threshold value of the device.

The coexistence interference thresholds in the device may be a triggering condition for the interference direction from ISM to LTE as a value related to the measured value of the LTE downlink.

The ICO measurement setting information may further include an ICO related maximum power reduction (ICO-MPR). ICO-MPR is a value used when lowering the maximum transmit power value in LTE uplink to reduce interference from LTE to ISM. The LTE uplink maximum transmit power value will be reduced by the corresponding value. As with P-MPR, the final maximum transmit power will be reduced by applying the greatest number in the comparison of MPR, A-MPR, P-MPR and ICO-MPR. The ICO-MPR determines the entry / exit (in / out) of coexistence interference in the device. ICO-MPR includes ICO-MPR_in and ICO-MPR_out.

At this time, only one of the coexistence interference threshold value (coexistence interference threshold value or coexistence interference threshold value in the device) or ICO-MPR (ICO-MPR_in or ICO-MPR_out) can be set as a condition for triggering have. (ICO-MPR_in or ICO-MPR_out) is set to be used as a triggering condition, and either one of them is set to be used as the triggering condition It can be set to perform triggering.

ICO-MPR (ICO-MPR_in or ICO-MPR_out) or ICO-MPR_out may be different values for each frequency band, and all frequency bands May be the same value.

At this time, the information can be transmitted as one element of the ReportConfigEUTRA information element in the RRC message in the following form. Table 3 below shows the triggering configuration of another event.

eventIdc-r11 SEQUENCE { IdcEntryThr-r11 INTEGER (-30..30), IdcResvThr-r11 INTEGER (-30..30), IdcMprInThr-r11 INTEGER (-30..30), RecIdcMprOutThr-r11 INTEGER (-30..30), }

The MS transmits a RRC reconfiguration complete message to the BS (S1410). And an acknowledgment of the RRC connection re-establishment message.

The UE performs the measurement considering the coexistence interference in the device and the measurement not considering the coexistence interference in the device (S1415). The measurement can be performed by using each measurement sample, distinguishing between a portion of the coexistence interference in the device and a portion of the device that is not affected by the coexistence interference. That is, a measurement sample having an influence of the coexistence interference in the apparatus is distinguished from a measurement sample having no influence of coexistence interference in the apparatus.

First, measurement rules for acquiring measurement samples are described. The rule that the UE acquires the measurement samples is also referred to as UE internal coordination.

FIG. 17 is an explanatory view for explaining measurement rules for obtaining measurement samples in an interference weak band applied to the present invention; FIG.

Referring to FIG. 17, the terminal can obtain a measurement sample based on the first measurement rule. For example, the UE does not obtain a measurement sample in a section where coexistence interference occurs in the apparatus (hereinafter referred to as an interference section), and in a section where coexistence interference does not occur in the apparatus (hereinafter, a non-interference section) . At this time, the UE can obtain measurement samples in every subframe, a certain subframe, or an arbitrary subframe in the non-interference period. Here, the second network system refers to a network system that is attacked by interference when co-existence interference occurs in the apparatus. For example, when the ISM receiver is interfered with by the LTE uplink, the ISM becomes the second network system. Conversely, when the ISM transmitter receives interference from the receiving end of the LTE downlink, the LTE system will be the second network system. Also, when coexistence interference occurs in a device, a network system that provides the effect of interference is referred to as a first network system.

Alternatively, the terminal may obtain a measurement sample based on the second measurement rule. For example, the UE obtains a measurement sample for the second network system in the non-interference period as in the first measurement rule, and a measurement sample in which the coexistence interference in the device is removed by the interference cancellation technique in the interference period. Therefore, the measurement sample in the non-interference period will be purely the measurement value for the second network system. The specific interference cancellation technique is an implementation issue of the terminal. Any interference cancellation technique may be used for the implementation of the second measurement rule.

When the measurement report is performed on the basis of the measurement sample according to the first or second measurement rule, the terminal can inform the base station of the pure channel value of only the second network system in the interference weak band. In this case, the interference-weakened band may be a band in which coexistence interference is in progress in the device or a band in which coexistence interference in a potential device is in progress.

When a measurement sample is obtained on the basis of RSRQ (Reference Signal Received Quality) or RSRP (Reference Signal Received Power), the measurement samples according to the first and second measurement rules are conceptually expressed by Equation (1).

Where S is the strength of the received signal in the second network system, I is the strength of the interference signal (not co-located interference in the device) acting on the second network system, and N is the strength of the noise. That is, it means the relative ratio of the interference of the received signal to the noise. The concrete implementation will follow the process of obtaining the corresponding concept of the wireless system.

In the case of obtaining measurement samples based on RSRP, the measurement samples according to the first and second rules are conceptually expressed by the following equation (2).

Here, S denotes the strength of the received signal in the second network system. That is, it means the strength of the received signal in the corresponding serving cell in the second network system. The concrete implementation will follow the process of obtaining the corresponding concept of the wireless system.

18 is an explanatory view for explaining a measurement rule for obtaining measurement samples in the interference flaw band according to another example of the present invention.

Referring to FIG. 18, a UE obtains a measurement sample based on a first measurement rule in a non-interference period, and a measurement sample based on a third measurement rule in an interference period.

According to the third measurement rule, the terminal can obtain two kinds of measurement samples in the same subframe. As an example, the terminal obtains a first measurement sample for the intra-device coexistence interference signal itself by the first network system and a second measurement sample for the signal of the second network system, respectively. That is, the UE obtains a first measurement sample using an interference cancellation technique that extracts only a signal of the first network system in an interference period, and obtains a second measurement sample using an interference cancellation technique that extracts only a signal of the second network system . This allows the terminal to report measurements to the base station with two measurements based on two independent measurement samples.

As another example, the terminal obtains a first measurement sample that reflects the coexistence interference signal in the device, and obtains a second measurement sample of the signal of the second network system from which the interference is removed. In this case, the first measurement sample is conceptually expressed by Equation (3), and the second measurement sample is conceptually expressed by Equation (1).

Where I 'is the intensity of coexistence interference in the device. That is, the UE can obtain the first measurement sample without the interference cancellation technique in the interference period and the second measurement sample using the interference cancellation technique that extracts only the signal of the second network system. In this case, there is no restriction on the measurement sample.

In yet another embodiment, the first measurement sample may be conceptually expressed as: " (4) "

Where I 'is the intensity of coexistence interference in the device. That is, the UE can obtain the first measurement sample by measuring only the strength of the interference by the first network in the interference period, and obtain the second measurement sample by using the interference cancellation technique that extracts only the signal of the second network system. It is possible to obtain only the first measurement sample in the interference period according to the third rule. That is, there may be a case where two samples can not be obtained simultaneously in the interference section.

A method of obtaining the two measured values used in the measurement report with the measurement samples obtained in Fig. 18 will be described.

In the embodiment, one measurement value is obtained through filtering by using the second measurement samples obtained by the third rule and the measurement samples obtained by the first rule. The first measurement samples obtained by the third rule and the measurement samples obtained by the first rule are filtered to obtain another measurement value.

In another embodiment, a measurement value is obtained through filtering with only measurement samples obtained by the first rule in the sample obtained by the third rule. That is, one measurement value is obtained through filtering with only measurement samples in a non-interference period. Another measurement value is obtained with only the first measurement samples obtained by the third rule. That is, another measurement value is obtained through filtering with only the first measurement samples in the interference period.

This third measurement rule can be applied not only to the FDM based interference adjustment but also to the TDM based interference adjustment.

According to the third measurement rule, the measurement report may include measurement rule information. The measurement rule information may indicate that the measurement report includes measurements taking into account co-existing interference in the equipment. For example, measurement rule information indicates that a measurement is obtained based on a measurement sample that considers coexistence in the device. In this case, the measurement report includes a measurement sample for a pure second network system that does not include intra-device coexistence interference, and a measurement sample that includes coexistence interference.

On the other hand, the measurement report may not include measurement rule information. In this case, if a measurement report for an interfering vulnerable band is received, the base station implicitly recognizes that the measurement report includes measurements taking into account intra-device coexistence interference.

On the other hand, the entity (e.g., terminal) performing the measurement may be one entity. Alternatively, there may be a plurality of individuals performing the measurements. For example, entities that perform measurements that take into account coexistence in the device and those that perform measurements that do not take into account coexistence in the device may exist independently of each other.

Referring back to FIG. 14, in step S1420, the terminal triggers an IDC entry triggering an event indicating that the coexistence interference in the device has started to be used in the available frequency band. At this time, the coexistence interference entry threshold value or the ICO-MPR_in value may be used. In other words, by comparing the measurement result considering the coexistence interference in the device with the measurement result not considering the coexistence interference in the device, the measurement result considering the coexistence interference in the device is larger than the measurement result not considering the coexistence interference in the device, If it exceeds the entry threshold, it triggers an event indicating that the on-device coexistence in-state (in-going IDC) state has started at the frequency. Or if the ICO-MPR value is greater than the ICO-MPR_in value, an event may be triggered indicating that the on-going co-existence IDC state has begun.

At this time, the triggering can be performed only for the serving cell and for both the serving cell and the neighboring cell. Here, the term " performed for both the serving cell and the neighboring cell means that if either of the serving cell and the neighboring cell satisfies the triggering condition, it triggers an event indicating that coexistence in-device IDC has started do.

As another example, the terminal may perform triggering using only measurement samples that are not affected by intra-device coexistence interference. At this time, the triggering is a case where triggering is performed for mobility. That is, since the triggering condition for the mobility is satisfied, the triggering of the intra-device coexistence interference control operation can be performed.

The UE reports a measurement result and an IDC indication to the base station as a result of the event triggering (S1425). The device coexistence interference generation indicator may include information on an unusable frequency band and a time division multiplex (TDM) pattern available at a corresponding frequency due to intra-device coexistence interference.

The unusable frequency band information may include frequency band range information.

Alternatively, the unusable frequency band information may include a frequency band indicator used in the LTE band. For example, it may include information of "band 7", "band 38", or "band 40" in FIG. The terminal may indicate an unusable frequency band through the frequency band indicator.

Alternatively, the unusable frequency band information may include an E-UTRA Absolute Radio Frequency Channel Number (EARFCN) used in the LTE band. The terminal may indicate an unusable frequency band through the absolute frequency indicator.

Alternatively, the unusable frequency band information may include a cell index. The UE may indicate that the cell related frequency indicated by the cell index is the unusable frequency band.

The coexistence interference indicator in the device includes at least one of an IDC Entry Threshold, an IDC Resolve Threshold, an MPR_in parameter (ICO MPR in Threshold), or an MPR_out parameter (ICO MPR out threshold). If the coexistence interference in the device exceeds the entry threshold, the coexistence interference parameter is less than the threshold, the MPR_in parameter exceeds the ICO-MPR_in value, The MPR_out parameter indicates a case where intra-device coexistence interference is resolved below the ICO-MPR_out value, respectively. Using each parameter, the co-presence indicator in the device may indicate what type of triggering the terminal's triggering is.

The measurement result may include only the measurement result of the portion without influence of the coexistence interference in the device.

Alternatively, the measurement result may include a measurement result for a part that is not influenced by coexistence interference in the device and a measurement result for a part that is influenced by coexistence interference in the device.

Alternatively, the measurement result may be a measurement result of a part that is not influenced by the coexistence interference in the apparatus and a measurement result of the part that is not influenced by the coexistence interference in the apparatus and a difference value .

In addition, the measurement result may be configured as a new component in the MeasResults information element. As an example, measResultIdc-r11.

The base station selects the most suitable coexistence interference control method (ICO scheme) based on the measurement result and the intra-device coexistence interference generation indicator (S1430), and the base station transmits the coexistence interference control operation between the terminal and the device (S1435 ). The corresponding control operation is transmitted from the base station to the mobile station, and the transmitted operation is performed between the base station and the mobile station. At this time, the intra-device coexistence interference control operation may be an FDM operation or a TDM operation. FDM operation can be performed through RRC connection reset. The TDM operation may be performed through a TDM pattern indication or a discontinuous reception (DRX) reset. In addition, the FDM operation or the TDM operation may be an operation according to the above-mentioned FIG. 5 to FIG.

Here, when a problem occurs in a frequency band in which a service is provided, a usable frequency that can be used does not cause a problem due to load balancing, and according to the measurement result, (For example, if the RSRP or RSRQ value of the corresponding frequency band is sufficiently large), the FDM operation is performed. Otherwise, the TDM operation is performed in the serving cell .

After the coexistence interference control operation is performed in the device, the UE performs the measurement considering the coexistence interference in the device and the measurement without considering the coexistence interference in the device (S1440). The measurement can be performed by distinguishing between the part of the coexistence interference in the device and the part of the device where the coexistence interference is not affected.

In step S1445, the UE triggers IDC release triggering that the intra-device coexistence interference has been completed for the unusable frequency band. Here, the termination of the coexistence interference in the device means that the coexistence interference in the device is sufficiently small or extremely rare in the corresponding frequency band, so that it is not difficult to communicate. At this time, the coexistence interference cancellation threshold value or the ICO-MPR_out value may be used. That is, in the case of on-going IDC, the measurement result considering the coexistence interference in the device and the coexistence interference in the device for the frequency band which is difficult to use due to the coexistence interference in the device An event may be triggered indicating that the frequency band that is determined to be difficult to use due to coexistence interference in the device can be reused if the difference value falls below the coexistence interference reduction threshold value of the device. Or if the ICO-MPR value is less than the ICO-MPR_out value, an event may be triggered indicating that the on-going co-existence IDC state has been resolved in the corresponding frequency band.

At this time, the triggering may be performed only for the serving cell, or for both the serving cell and the neighboring cell.

The terminal reports the measurement result and the intra-device coexistence interference generation indicator to the base station (S1450). The device co-existence interference occurrence indicator may include information on unusable frequency band information and possible TDM patterns at the corresponding frequency due to intra-device coexistence interference. At this time, the unusable frequency band information may be information updated due to the intra-device coexistence interference control operation performed before the step. In addition, the measurement result may further include a release report.

If coexistence interference control is required in the device, the base station selects again the most appropriate coexistence interference control method based on the measurement result and coexistence interference generation indicator in the device (S1455), and the base station performs coexistence interference control (S1460). At this time, the intra-device coexistence interference control operation may be an FDM operation or a TDM operation. FDM operation can be performed through RRC connection reset. The TDM operation may be performed through a DRX reset or by indicating a TDM pattern. Here, when a problem occurs in a frequency band in which a service is provided, if the frequency band that can be used does not cause a problem due to load balancing and it is determined according to the measurement result that there is no significant influence on the handover (for example, Performs an FDM operation if the RSRP or RSRQ value of the frequency band is sufficiently large, and otherwise performs a TDM operation in the serving cell.

FIG. 15 (FIGS. 15A and 15B) is a flowchart showing another example of operation of a terminal and a base station that perform intra-device coexistence interference control. The initialization setting operation of the terminal is related to the operation in which the base station transmits system information.

Referring to FIG. 15, a base station transmits a system information block (SIB) to a mobile station (S1500). At this time, the system information (SIB) transmitted by the base station may include intra-device coexistence interference control measurement setup information (ICO measurement setup information). The ICO measurement setup information includes a coexistence interference control triggering condition in the base station, and specifically includes an IDC entry threshold value indicating that the coexistence interference in the device is on-going at the corresponding frequency (on-going IDC) ) Information, and an IDC release threshold information indicating that the frequency band that is difficult to use due to coexistence interference in the device can be reused. The coexistence interference cancellation threshold value of the device can be set to the same value as the coexistence interference entry threshold value of the device. The coexistence interference thresholds in the device may be a triggering condition for the interference direction from ISM to LTE as a value related to the measured value of the LTE downlink.

In addition, the ICO measurement setting information further includes an ICO-MPR for determining in / out of coexistence interference in the device. ICO-MPR includes ICO-MPR_in and ICO-MPR_out.

At this time, only one of the intra-device coexistence interference threshold (entry threshold value or resolution threshold) or ICO-MPR (ICO-MPR_in, ICO-MPR_out) can be set to be used as a condition for triggering. (ICO-MPR_in, ICO-MPR_out) is set to be used as a triggering condition. If either of the ICO-MPR_in and ICO-MPR_out is set to be used for triggering, .

The base station transmits an RRC connection re-establishment message to the mobile station (S1505), and the mobile station transmits an RRC reconfiguration complete message to the base station (S1510). And may include an acknowledgment of the RRC connection re-establishment message.

The UE performs measurement in consideration of coexistence interference in the device and measurement without consideration of coexistence interference in the device (S1515). The measurement can be performed by using each measurement sample to distinguish between the portion of the coexistence interference in the device and the portion of the device that is not affected by the coexistence interference. That is, a measurement sample having an influence of coexistence interference in the device is used separately from a measurement sample having no influence of coexistence interference in the device.

The terminal triggers an IDC entry triggering an event indicating that the intra-device coexistence interference has begun with respect to the usable frequency band (S1520). At this time, the coexistence interference entry threshold value or the ICO-MPR_in value may be used. In other words, by comparing the measurement result considering the coexistence interference in the device with the measurement result not considering the coexistence interference in the device, the measurement result considering the coexistence interference in the device is larger than the measurement result not considering the coexistence interference in the device, If it exceeds the entry threshold, it triggers an event indicating that the on-device coexistence in-state (in-going IDC) state has started at the frequency. Or if the ICO-MPR value is greater than the ICO-MPR_in value, an event may be triggered indicating that the on-going co-existence IDC state has begun.

At this time, the triggering can be performed only for the serving cell and for both the serving cell and the neighboring cell.

The UE reports the measurement result and the intra-device coexistence interference generation indicator to the BS as a result of the event triggering (S1525). The device coexistence interference generation indicator may include frequency band information that is difficult to use due to intra-device coexistence interference, and information on a TDM pattern available at the frequency. The measurement result may include only the measurement result of the part that is not influenced by the coexistence interference in the device. Alternatively, the measurement result may include a measurement result for a part affected by coexistence interference in the device and a measurement result for a part not affected by coexistence interference in the device.

The base station selects the coexistence interference control method most appropriate based on the measurement result and the intra-device coexistence interference generation indicator (S1530).

The base station transmits the coexistence interference control operation between the UE and the device (S1535). The corresponding control operation is transmitted from the base station to the mobile station, and the transmitted operation is performed between the base station and the mobile station. The coexistence interference control operation in the apparatus may be an FDM operation or a TDM operation. FDM operation can be performed through RRC connection reset. The TDM operation may be performed through a DRX reset or by indicating a TDM pattern.

Here, when a problem occurs in a frequency band in which a service is provided, if the frequency band that can be used does not cause a problem due to load balancing and it is determined according to the measurement result that there is no significant influence on the handover (for example, Performs an FDM operation if the RSRP or RSRQ value of the frequency band is sufficiently large, and otherwise performs a TDM operation in the serving cell. In addition, the FDM operation or the TDM operation may be an operation according to the above-mentioned FIG. 5 to FIG.

After performing the coexistence interference control operation in the apparatus, the terminal performs measurement taking into consideration intra-apparatus coexistence interference and measurement without consideration of coexistence interference in the apparatus (S1540). The measurement can be performed by distinguishing between the part of the coexistence interference in the device and the part of the device where the coexistence interference is not affected.

In addition, the UE triggers IDC release triggering that the coexistence interference in the device has been completed for the unusable frequency band (S1545). Here, the termination of the coexistence interference in the device means that coexistence interference in the device is sufficiently small or rarely occurs in the corresponding frequency band so that communication is not difficult. At this time, the coexistence interference cancellation threshold value or the ICO-MPR_out value may be used. That is, for frequency bands that are difficult to use due to coexistence in the device in the on-going IDC condition, the measurement result considering the coexistence interference in the device and the coexistence interference in the device An event may be triggered indicating that the frequency band that is determined to be difficult to use due to coexistence interference in the device can be reused if the difference value falls below the coexistence interference reduction threshold value of the device. Alternatively, if the ICO-MPR value is less than the ICO-MPR_out value, an event may be triggered indicating that the on-going co-existence IDC state has been resolved in the corresponding frequency band.

Triggering may be performed only on the serving cell and on both the serving cell and the neighboring cell.

The terminal reports the measurement result and the coexistence interference generation indicator in the device to the base station (S1550). The device co-existence interference occurrence indicator may include information on unusable frequency band information and possible TDM patterns at the corresponding frequency due to intra-device coexistence interference. At this time, the unusable frequency band information may be information updated due to the coexistence interference control operation performed in the apparatus. In addition, the measurement result may further include a resolution report.

If the coexistence interference control is required in the device, the base station selects the most suitable coexistence interference control method based on the measurement result and the intra-device coexistence interference generation indicator (S1555), and the base station performs the coexistence interference control operation (S1560). The coexistence interference control operation in the apparatus may be an FDM operation or a TDM operation. FDM operation can be performed through RRC connection reset. The TDM operation may be performed through a DRX reset or by indicating a TDM pattern. Here, when a problem occurs in a frequency band in which a service is provided, if the frequency band that can be used does not cause a problem due to load balancing and it is determined according to the measurement result that there is no significant influence on the handover (for example, Performs an FDM operation if the RSRP or RSRQ value of the frequency band is sufficiently large, and otherwise performs a TDM operation in the serving cell.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

Claims (12)

A method for controlling intra-device coexistence interference by a terminal in a wireless communication system,
Receiving from the base station coexistence interference control measurement setting information including a condition triggering a control operation of coexistence interference in the apparatus;
Performing measurement without consideration of coexistence interference in the device and coexistence interference in the device and determining whether coexistence interference in the device is in progress at the terminal;
Transmitting an intra-device coexistence interference indicator and a measurement result to the base station indicating whether intra-device coexistence interference is in progress; And
And receiving the coexistence interference control operation in the apparatus from the base station. delete delete delete delete delete A method for controlling intra-device coexistence interference by a base station in a wireless communication system,
Transmitting in-device coexistence interference control measurement setting information including a condition for triggering a control operation of coexistence interference in the device to the terminal;
Receiving an intra-device coexistence interference indicator and a measurement result from the terminal indicating whether coexistence in-device is in progress;
Determining an intra-device coexistence interference control operation based on the measurement result; And
And transmitting the determined coexistence interference control operation to the user equipment. delete delete delete delete delete

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