Abstract:
A method for improving a Distance Measure Equipment (DME) interference resisting capability of a Long Term Evolution (LTE) system are described in the present disclosure; at an LTE User Equipment (UE) side, the method includes that: a symbol level DME interference result is obtained, and a scheduling message is sent according to the obtained symbol level DME interference result or according to the obtained symbol level DME interference result and a Physical Downlink Shared Channel (PDSCH) scheduling situation of a current subframe; at an LTE evolved Node B (eNB) side, the method includes that: the received scheduling message is detected, and a subframe is scheduled according to the received scheduling message. The present disclosure also discloses a UE, an eNB and two computer storage media for improving the DME interference resisting capability of the LTE system.

Description:
TECHNICAL FIELD 
     The present disclosure relates to a Long Term Evolution (LTE) technology, and more particularly, to a method, device and storage medium for improving a Distance Measure Equipment (DME) interference resisting capability of an LTE system. 
     BACKGROUND 
     LTE technology is a technology taking Orthogonal Frequency Division Multiplexing (OFDM)/Frequency Division Multiplexing Access (FDMA) as a core, and it is considered as a quasi-4G technology. Being compared with the 2G/3G technology, the LTE technology has advantages of providing a higher data rate, increasing cell capacity, reducing a system delay, supporting larger cell coverage and the like, so the LTE technology is increasingly favoured by communication operators, and its application range is extended from high-speed train communication to ground-to-air communication, for example, an aircraft communication system which enables passengers to enjoy data services on the flight. 
     At present, low-altitude communication airline coverage of the LTE is shown in  FIG. 1 ; a ground-to-air wireless channel is established by using an LTE evolved Node B (eNB)  10  for network layout along an airline, and taking an LTE User Equipment (UE)  20  as mechanical communication equipment (airborne LTE UE). The network layout of the LTE in a cabin is shown in  FIG. 2 ; after establishing a connection with the LTE eNB through an external antenna  30 , the airborne LTE UE connects a Wireless Fidelity (WiFi) Access Point (AP)  40  through an Ethernet in the cabin to build a wireless local area network, the passengers on the plane can use a smart phone, a Personal Digital Assistant (PDA), a portable computer and other devices to access to the wireless local area network, so as to realize services of surfing the Internet, receiving and sending emails, File Transfer Protocol (FTP) download and the like. 
     External antenna distribution of an airplane is shown in  FIG. 3 ; except the external antenna, a DME device antenna  50  which is necessary for the airplane is also installed at abdomen of the cabin; transmitting power of the DME is 57 dBm, and a downlink frequency point of the airborne LTE UE is just in a range of frequency point occupied by the DME, so when they work at the same time, a Carrier to Interference plus Noise Ratio (CINR) of a downlink channel of the airborne LTE UE is very low, which seriously influences downstream traffic of the LTE system. Because of being interfered, a subframe interfered by the DME will be retransmitted for many times because it cannot be validated; however, even the same Hybrid Automatic Repeat Request (HARQ) is retransmitted for many times, process data may still not be validated by a Cyclic Redundancy Check (CRC); thus, invalid retransmission of many times will waste wireless resources, and combination failure of many times will influence a Modulation and Coding Scheme (MCS) value of the LTE eNB scheduling the subsequent subframe, which causes a drop of the downstream traffic of the LTE system. 
     SUMMARY 
     In view of this, the present disclosure provides a method, device and storage medium for improving a DME interference resisting capability of an LTE system, which can effectively improve downstream traffic of the LTE system when being interfered by DME. 
     To this end, the technical solutions of the present disclosure are implemented as follows. 
     According to a first aspect of the present disclosure, a method for improving a DME interference resisting capability of an LTE system is provided, which includes that:
         a symbol level DME interference result is obtained; and   a scheduling message is sent according to the obtained symbol level DME interference result or according to the obtained symbol level DME interference result and a Physical Downlink Shared Channel (PDSCH) scheduling situation of a current subframe.       

     Preferably, the step of obtaining the symbol level DME interference result may include that:
         the symbol level DME interference result is obtained by comparing a power ratio between time domain data symbols with a preset threshold.       

     Preferably, the step of obtaining the symbol level DME interference result by comparing the power ratio between the time domain data symbols with the preset threshold may include that:
         when the power ratio between the time domain data symbols is greater than or equal to the preset threshold, it is determined that there is a symbol level DME interference.       

     Preferably, the step of sending the scheduling message according to the obtained symbol level DME interference result and the PDSCH scheduling situation of the current subframe may include that:
         when there is a symbol level DME interference and there is PDSCH scheduling at the current subframe, a Discontinuous Transmission (DTX) message is sent.       

     Preferably, the step of obtaining the symbol level DME interference result by comparing the power ratio between time domain data symbols with the preset threshold may include that:
         when the power ratio between the time domain data symbols is less than the preset threshold, it is determined that there is no symbol level DME interference.       

     Preferably, the step of sending the scheduling message according to the obtained symbol level DME interference result and the PDSCH scheduling situation of the current subframe may include that:
         when there is a symbol level DME interference and there is no PDSCH scheduling at the current subframe, an Acknowledgement (ACK) message is sent;   the step of sending the scheduling message according to the obtained symbol level DME interference result may include that:   when there is no symbol level DME interference, a Non-Acknowledgement (NACK) message is sent.       

     According to a second aspect of the present disclosure, a method for improving a DME interference resisting capability of an LTE system is provided, which includes that:
         a scheduling message is received, and a subframe is scheduled according to the received scheduling message.       

     Preferably, the step of scheduling the subframe according to the received scheduling message may include that:
         when a DTX message is received, an interfered subframe serving as newly transmitted data of an HARQ is scheduled again;   when an ACK message is received, an MCS value of a subsequent subframe is increased, and the subsequent subframe is scheduled; and   when a NACK message is received, the MCS value is decreased, and retransmitted data of an HARQ process is scheduled, and an HARQ combination is performed.       

     According to a third aspect of the present disclosure, a UE for improving a DME interference resisting capability of an LTE system is provided, which includes: a first downlink Physical (PHY) layer, a first Media Access Control (MAC) layer, and a first uplink PHY layer; wherein,
         the first downlink PHY layer is configured to obtain a symbol level DME interference result;   the first MAC layer is configured to inform the first uplink PHY layer to send the scheduling message according to the symbol level DME interference result sent by the first downlink PHY layer or according to the symbol level DME interference result and whether there is the PDSCH scheduling at a current subframe; and   the first uplink PHY layer is configured to send the scheduling message according to the information of the first MAC layer.       

     Preferably, the first downlink PHY layer may be configured to obtain the symbol level DME interference result by comparing the power ratio between time domain data symbols with the preset threshold. 
     Preferably, the first downlink PHY layer may be configured to, when the power ratio between the time domain data symbols is greater than or equal to the preset threshold, determine that there is a symbol level DME interference. 
     Preferably, the first MAC layer may include:
         a first processing module, which is configured to, when there is a symbol level DME interference and there is PDSCH scheduling at the current subframe, inform the first uplink PHY layer to send the DTX message.       

     Preferably, the first downlink PHY layer may be further configured to, when the power ratio between the time domain data symbols is less than the preset threshold, determine that there is no symbol level DME interference. 
     Preferably, the first MAC layer may include:
         a second processing module, which is further configured to, when there is a symbol level DME interference and there is no PDSCH scheduling at the current subframe, inform the first uplink PHY layer to send the ACK message; and   a third processing module, which is further configured to, when there is no symbol level DME interference, inform the first uplink PHY layer to send a NACK message.       

     According to a fourth aspect of the present disclosure, an eNB for improving a DME interference resisting capability of an LTE system is provided, which includes: a second uplink PHY layer, a second MAC layer and a second downlink PHY layer; wherein,
         the second uplink PHY layer is configured to detect in real time whether the scheduling message is received, and send the detected scheduling message to the second MAC layer;   the second MAC layer is configured to schedule the subframe according to the scheduling message sent by the second uplink PHY layer; and   the second downlink PHY layer is configured to send downlink time domain data to a first downlink PHY layer according to scheduling information of the second MAC layer.       

     Preferably, the second MAC layer is configured to, when a DTX message is received, schedule again the interfered subframe serving as the newly transmitted data of the HARQ, when an ACK message is received, increase a MCS value of a subsequent subframe and schedule the subsequent subframe, and when a NACK message is received, decrease the MCS value of the subsequent subframe, schedule the retransmitted data of the HARQ process, and perform the HARQ combination. 
     According a fifth aspect of the present disclosure, a computer storage medium is provided, in which a computer executable instruction is stored; the computer executable instruction is used for performing the method in any technical solution according to the first aspect of the present disclosure. 
     According a sixth aspect of the present disclosure, a computer storage medium is provided, in which a computer executable instruction is stored; the computer executable instruction is used for performing the method in any technical solution according to the second aspect of the present disclosure. 
     With the method, device and storage medium for improving the DME interference resisting capability of the LTE system which are provided by the present disclosure, at the LTE UE side, the symbol level DME interference result is obtained, and the corresponding scheduling message is sent according to the obtained symbol level DME interference result or according to the obtained symbol level DME interference result and the PDSCH scheduling situation of the current subframe; at the LTE eNB side, the subframe is scheduled according to the received scheduling message; thus, the DME can only influence the interference subframe, but not decrease the MCS value of the adjacent subframe; besides, a waste of wireless resources will not be caused by retransmitting interference subframe data for many times, and the downstream traffic of the LTE system when being interfered by the DME can be effectively improved. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a schematic diagram of low-altitude communication airline coverage of LTE; 
         FIG. 2  is a schematic diagram of network layout of LTE in a cabin; 
         FIG. 3  is a schematic diagram of external antenna distribution of an airplane; 
         FIG. 4  is a basic implementation flowchart of a method for improving a DME interference resisting capability of an LTE system at an LTE UE side provided by the present disclosure; 
         FIG. 5  is a basic implementation flowchart of a method for improving a DME interference resisting capability of an LTE system at an LTE eNB side provided by the present disclosure; 
         FIG. 6  is a specific implementation flowchart of a method for improving a DME interference resisting capability of an LTE system at an LTE UE side provided by the present disclosure; 
         FIG. 7  is a specific implementation flowchart of a method for improving a DME interference resisting capability of an LTE system at an LTE eNB side provided by the present disclosure; 
         FIG. 8  is a structure diagram of a UE for improving a DME interference resisting capability of an LTE system provided by the present disclosure; 
         FIG. 9  is a structure diagram of an eNB for improving a DME interference resisting capability of an LTE system provided by the present disclosure; and 
         FIG. 10  is a structure diagram of a device for implementing a method for improving a DME interference resisting capability of an LTE system provided by the present disclosure. 
     
    
    
     DETAILED DESCRIPTION 
     The preferred embodiments of the present disclosure are elaborated below in combination with the accompanying drawings; it should be understood that the preferred embodiments elaborated below are only used for elaborating and illustrating the present disclosure and not intended to limit the present disclosure. 
     Methods for improving a DME interference resisting capability of an LTE system in the present disclosure include a method at a terminal side and a method at a base station side. 
     The method at the terminal side includes that: a symbol level DME interference result is obtained; and
         a scheduling message is sent according to the obtained symbol level DME interference result or according to a DME and a PDSCH scheduling situation of a current subframe.       

     The method at the base station includes that: a scheduling message is received, wherein the scheduling message is sent by the terminal according to the obtained symbol level DME interference result or according to the DME and the PDSCH scheduling situation of the current subframe; and
         a subframe is scheduled according to the scheduling message.       

     The symbol level interference result includes that there is a symbol level DME interference and there is no symbol level DME interference;
         when there is no symbol level DME interference, the UE sends an NACK message only according to the symbol level DME interference result;   when there is the symbol level DME interference, the UE can further determine a type of the sent scheduling message according to the PDSCH scheduling situation of the current subframe;   specifically, when there is the symbol level DME interference and there is PDSCH scheduling at the current subframe, a DTX message is sent; when there is the symbol level DME interference and there is no PDSCH scheduling at the current subframe, an ACK message is sent.       

     In the present disclosure, the LTE UE and the LTE eNB respectively include an uplink PHY layer, a downlink PHY layer and an MAC layer; for describing conveniently, the uplink PHY layer, the downlink PHY layer and the MAC layer of the LTE UE are called the first uplink PHY layer, the first downlink PHY layer and the first MAC layer; the uplink PHY layer, the downlink PHY layer and the MAC layer of the LTE eNB are called the second uplink PHY layer, the second downlink PHY layer and the second MAC layer. 
     Specifically, a terminal for implementing the method at the terminal side may include the following structure:
         a first downlink PHY layer, configured to obtain a symbol level DME interference result;   a first MAC layer, configured to judge a situation that a current subframe is interfered by a DME according to the symbol level DME interference result sent by the first downlink PHY layer or according to the symbol level DME interference result and whether there is the PDSCH scheduling at the current subframe, and inform a first PHY layer to send a scheduling message; and   a first uplink PHY layer, configured to send the scheduling message according to the information of the first MAC layer.       

     Here, the first MAC layer can be divided into a first processing module, a second processing module and a third processing module; wherein
         the first processing module is configured to, when there is the symbol level DME interference and there is the PDSCH scheduling at the current subframe, inform the first uplink PHY layer to send the DTX message;   the second processing module is configured to, when there is the symbol level DME interference and there is no PDSCH scheduling at the current subframe, inform the first uplink PHY layer to send the ACK message; and   the third processing module is configured to, when there is no symbol level DME interference, determine that the current subframe is not interfered by the DME, and inform the first uplink PHY layer to send the NACK message.       

     Specifically, the base station for implementing the method at the base station side may include the following structure:
         a second uplink PHY layer, configured to detect in real time whether a scheduling message is received, and send the detected scheduling message to a second MAC layer;   the second MAC layer, configured to schedule a subframe according to the scheduling message sent by the second uplink PHY layer; and   a second downlink PHY layer, configured to send downlink time domain data to the first downlink PHY layer according to scheduling information of the second MAC layer.       

     In the present disclosure, the first downlink PHY layer obtains a symbol level DME interference result by comparing a power ratio between time domain data symbols with a preset threshold;
         wherein, data will be saturated when a DME signal comes, then the preset threshold can be calculated according to the power ratio between the saturated data and normal data of a wireless receiving device; generally, the range of the preset threshold may be 2 dB-10 dB.       

     Determining whether the current subframe is interfered by the DME according to the obtained symbol level DME interference result and the PDSCH scheduling situation of the current subframe, and sending the corresponding scheduling message specifically includes that:
         if there is the symbol level DME interference and there is the PDSCH scheduling at the current subframe, the first MAC layer determines that the current subframe is interfered by the DME, and informs the first uplink PHY layer to send the DTX message;   if there is the symbol level DME interference and there is no PDSCH scheduling at the current subframe, the first MAC layer determines that the current subframe is not interfered by the DME, and informs the first uplink PHY layer to send the ACK message; and   if there is no DME interference, the first MAC layer determines that the current subframe is not interfered by the DME, and informs the first uplink PHY layer to send the NACK message.       

     The LTE eNB side scheduling according to the received scheduling message specifically includes that:
         after the second MAC layer receives the DTX message, the interfered subframe is scheduled again as newly transmitted data of HARQ, and an HARQ combination is not performed on the interfered subframe;   after the second MAC layer receives the ACK message, the second MAC layer increases an MCS value of the subsequent subframe while scheduling a subsequent subframe;   after the second MAC layer receives the NACK message, the second MAC layer decreases an MCS value of the subsequent subframe while scheduling retransmitted data of a corresponding HARQ process, and performs the HARQ combination.       

     In the method for improving the DME interference resisting capability of the LTE system of the present disclosure, as shown in  FIG. 4 , the basic implementation flow at the LTE UE side includes the following steps: 
     Step  101 : a symbol level DME interference result is obtained;
         here, the first downlink PHY layer obtains the symbol level DME interference result by comparing the power ratio between time domain data symbols with the preset threshold, and sends the obtained result to the first MAC layer;   wherein, for the preset threshold, because the data will be saturated when the DME signal comes, the preset threshold can be calculated according to the power ratio between the saturated data and the normal data of the wireless receiving device; the range of the preset threshold can be 2 dB-10 dB;       

     Step  102 : a situation that a current subframe is interfered by the DME is judged according to the obtained symbol level DME interference result and a PDSCH scheduling situation of the current subframe, and the corresponding scheduling message is sent;
         herein, the first MAC layer determining whether the current subframe is interfered by the DME according to the symbol level DME interference result reported by the first downlink PHY layer and whether there is the PDSCH scheduling at the current subframe specifically includes that:   if there is the symbol level DME interference and there is the PDSCH scheduling at the current subframe, it is determined that the current subframe is interfered by the DME;   if there is the symbol level DME interference and there is no PDSCH scheduling at the current subframe, it is determined that the current subframe is not interfered by the DME; and   if there is no symbol level DME interference, it is determined that the current subframe is not interfered by the DME;   correspondingly, the first MAC layer sending the corresponding scheduling message according to the symbol level DME interference result of the current subframe specifically includes that:   if the current subframe is interfered by the DME, the first MAC layer informs the first uplink PHY layer to send the DTX message;   if the current subframe is not interfered by the DME, the first MAC layer informs the first uplink PHY layer to send the ACK/NACK message;   correspondingly, the first PHY layer sends the DTX message or the ACK/NACK message according to the information of the first MAC layer.       

     Here, how to send the DTX message or the ACK/NACK message belongs to the related art, which will not be repeated here. 
     In the method for improving the DME interference resisting capability of the LTE system of the present disclosure, as shown in  FIG. 5 , the basic implementation flow at the LTE eNB side includes the following steps: 
     Step  201 : a received scheduling message is detected;
         herein, the second uplink PHY layer detects in real time whether the scheduling message is received, that is, whether the DTX message or the ACK/NACK message is received, and sends the detected DTX message or ACK/NACK message to the second MAC layer.       

     Step  202 : a subframe is scheduled according to the received scheduling message;
         specifically, after the second MAC layer receives the DTX message, the interfered subframe is scheduled again as the newly transmitted data of the HARQ; scheduling again avoids a long-spaced narrow pulse interference of the DME, and not performing the HARQ combination on the interfered subframe does not influence the MCS value of the PDSCH of the subsequent subframe;   after the second MAC layer receives the ACK message, the second MAC layer increases the MCS value of the subsequent subframe while scheduling the subsequent subframe;   after the second MAC layer receives the NACK message, the second MAC layer decreases the MCS value of the subsequent subframe while scheduling the retransmitted data of the corresponding HARQ process, and performs the HARQ combination.       

     After step  202 , the method may further include that: the second downlink PHY layer of the LTE eNB performs the subsequent processing according to an LTE protocol; how to perform belongs to the related art, which will not be repeated here. 
     The technical solutions of the present disclosure are further elaborated below in combination with the accompanying drawings and specific embodiments. 
     As shown in  FIG. 6 , the specific implementation flow of a method for improving a DME interference resisting capability of an LTE system at an LTE UE side includes the following steps. 
     Step  301 : a symbol level DME interference result is obtained, and the obtained result is sent to a first MAC layer;
         specifically, a first downlink PHY layer obtains the symbol level DME interference result by calculating and comparing the power ratio between the adjacent symbols of the time domain data symbols 0-13 with the preset threshold, and sends the result to the first MAC layer;   for the preset threshold, because the data will be saturated when the DME signal comes, the preset threshold can be calculated according to the power ratio between the saturated data and the normal data of the wireless receiving device; the range of the preset threshold can be 2 dB-10 dB; in the present embodiment, the preset threshold is 6 dB;   wherein, the symbol level DME interference result is expressed by a bit stream bit 0 -bit 13  of 14 bits; the specific definition is that: bit 0  being equal to 1 indicates that the power ratio between the symbol 0 and the previous frame symbol 13 is greater than or equal to the threshold, and it is determined that there is the symbol level DME interference; bit 0  being equal to 0 indicates the power ratio between the symbol 0 and the previous frame symbol 13 is less than the threshold, and it is determined that there is no symbol level DME interference; bit 1  being equal to 1 indicates that the power ratio between the symbol 1 and the symbol 0 is greater than or equal to the threshold, and it is determined that there is the symbol level DME interference; bit 1  being equal to 0 indicates that the power ratio between the symbol 1 and the symbol 0 is less than the threshold, it is determined that there is no symbol level DME interference; by that analogy, it is determined whether there is the symbol level DME interference in the following.       

     Step  302 : a situation that a current subframe is interfered by a DME is judged;
         the first MAC layer determining whether the current subframe is interfered by the DME according to the symbol level DME interference result reported by the first downlink PHY layer and whether there is PDSCH scheduling at the current subframe specifically includes that:   if there is the symbol level DME interference and there is the PDSCH scheduling at the current subframe, it is determined that the current subframe is interfered by the DME;   if there is the symbol level DME interference and there is no PDSCH scheduling at the current subframe, it is determined that the current subframe is not interfered by the DME; and   if there is no symbol level DME interference, it is determined that the current subframe is not interfered by the DME.       

     Step  303 : a corresponding scheduling message is sent according to the situation that the current subframe is interfered by the DME;
         specifically, if the current subframe is interfered, the first MAC layer informs a first uplink PHY layer to send the DTX message;   if the current subframe is not interfered, the first MAC layer informs the first uplink PHY layer to send the ACK/NACK message;   correspondingly, the first PHY layer sends the DTX message or the ACK/NACK message according to the information of the first MAC layer.       

     Here, how to send the DTX message or the ACK/NACK message belongs to the related art, which will not be repeated here. 
     After steps  301 - 303  are performed, the LTE eNB performs the subsequent processing according to the scheduling message sent by the first uplink PHY layer to form a processing method in which the LTE UE and the LTE eNB interact; as shown in  FIG. 7 , the specific implementation flow of a method for improving a DME interference resisting capability of an LTE system at an LTE eNB side of the present disclosure includes the following steps. 
     Step  401 : a received scheduling message is detected;
         herein, a second uplink PHY layer detects in real time whether a scheduling message is received, that is, whether a DTX message or an ACK/NACK message is received, and sends the detected DTX message or ACK/NACK message to a second MAC layer.       

     Step  402 : it is determined whether the received message is a DTX message; if so, perform step  403 ; otherwise, perform step  404 ;
         here, the second MAC layer determines whether the received message is the DTX message.       

     Step  403 : an interfered subframe is scheduled again, and then the current processing flow is ended;
         specifically, the second MAC layer schedules again the interfered subframe serving as the newly transmitted data of the HARQ; scheduling again avoids the long-spaced narrow pulse interference of the DME, and not performing the HARQ combination on the interfered subframe does not influence the MCS value of the PDSCH of the subsequent subframe.       

     Step  404 : the processing is performed according to an LTE protocol;
         herein, after the second MAC layer receives an ACK message, the second MAC layer increases an MCS value of the subsequent subframe while scheduling the subsequent subframe;   after the second MAC layer receives a NACK message, the second MAC layer decreases the MCS value of the subsequent subframe while scheduling the retransmitted data of the corresponding HARQ process, and performs the HARQ combination.       

     After step  404 , the method may further include that: the second downlink PHY layer performs the subsequent processing according to the LTE protocol; how to perform belongs to the related art, which will not be repeated here. 
     With the method for improving the DME interference resisting capability of the LTE system provided by the present disclosure, when a threshold is set as 6 dB, downstream traffic of the LTE system when being interfered by the DME can be improved from 13% of the traffic without interference to 80% of the traffic without interference, which not only saves the traffic, but also avoids the waste of wireless resources. 
     For implementing the method for improving the DME interference resisting capability of the LTE system, the present disclosure also provides a UE for improving a DME interference resisting capability of an LTE system; as shown  FIG. 8 , the structure of the UE for improving the DME interference resisting capability of the LTE system includes: a first downlink PHY layer  11 , a first MAC layer  12  and a first uplink PHY layer  13 ; wherein,
         the first downlink PHY layer  11  is configured to obtain a symbol level DME interference result;   herein, the first downlink PHY layer obtains the symbol level DME interference result by comparing a power ratio between time domain data symbols with the preset threshold, and sends the obtained result to the first MAC layer;   the first MAC layer  12  is configured to judge a situation that the current subframe is interfered by a DME according to the symbol level DME interference result sent by the first downlink PHY layer and whether there is PDSCH scheduling at a current subframe, and inform the first PHY layer to send a corresponding scheduling message;   the first MAC layer  12  judging the situation that the current subframe is interfered by the DME according to the symbol level DME interference result sent by the first downlink PHY layer and whether there is the PDSCH scheduling at the current subframe is specifically that:   if there is the symbol level DME interference and there is the PDSCH scheduling at the current subframe, then it is determined that the current subframe is interfered by the DME;   if there is the symbol level DME interference and there is no PDSCH scheduling at the current subframe, then it is determined that the current subframe is not interfered by the DME;   if there is no symbol level DME interference, then it is determined that the current subframe is not interfered by the DME;       

     The first MAC layer  12  scheduling correspondingly according to the symbol level DME interference result of the current subframe is specifically that:
         when the current subframe is interfered by the DME, the first MAC layer  12  informs the first uplink PHY layer  13  to send the DTX message;   when the current subframe is not interfered by the DME, the first MAC layer  12  informs the first uplink PHY layer  13  to send the ACK/NACK message;   the first uplink PHY layer  13  is configured to send the DTX message or the ACK/NACK message according to the information of the first MAC layer  12 .       

     For implementing the method for improving the DME interference resisting capability of the LTE system, the present disclosure also provides an eNB improving a DME interference resisting capability of an LTE system; as shown  FIG. 9 , the structure of the eNB for improving the DME interference resisting capability of the LTE system includes: a second uplink PHY layer  21 , a second MAC layer  22  and a second uplink PHY layer  23 ; wherein,
         the second uplink PHY layer  21  is configured to detect in real time whether a scheduling message is received, and send the detected scheduling message to the second MAC layer;   specifically, the uplink PHY layer  21  sends a DTX message or an(a) ACK/NACK message sent by the first uplink PHY layer  13  to the second MAC layer  22 ;   the second MAC layer  22  is configured to schedule according to the scheduling message sent by the second uplink PHY layer  21 ;   specifically, the second MAC layer  22  is configured to, when the received message is the DTX message, schedule again the interfered subframe serving as the newly transmitted data of the HARQ;   the second MAC layer  22  is configured to, when the ACK message is received, increase an MCS value of a subsequent subframe and schedule the subsequent subframe;   the second MAC layer  22  is configured to, when the NACK message is received, decrease the MCS value of the subsequent subframe, schedule the retransmitted data of the HARQ process, and perform the HARQ combination;   the second downlink PHY layer  23  is configured to send downlink time domain data to the first downlink PHY layer  11  according to the scheduling information of the second MAC layer  22 .       

     Note that, in practical applications, functions of the first MAC layer  12  and the second MAC layer  22  can be implemented by a Central Processing Unit (CPU), and/or a Micro Processing Unit (MPU); functions of the first downlink PHY layer  11 , the first uplink PHY layer  13 , the second uplink PHY layer  21  and the second downlink PHY layer can be implemented by a Digital Signal Processor (DSP), and/or a Field-Programmable Gate Array (FPGA). The CPU, and/or the MPU, and/or the DSP, and/or the FPGA can be respectively at the LTE UE side, and/or the LTE eNB side. 
     The present disclosure also records a computer storage medium in which a computer executable instruction is stored; the computer executable instruction is used for performing the method described in any technical solution at the base station side. 
     The present disclosure also records another computer storage medium in which a computer executable instruction is stored; the computer executable instruction is used for performing the method described in any technical solution at the base station side. 
     The storage medium can be a USB flash disk, a compact disc, a digital video disk or a mobile hard disk, and so on; a non-instant storage medium is preferable. 
     The present disclosure also provides a device shown in  FIG. 10 ; the device includes a processor  52 , a storage medium  54  and at least one external communication interface  51 ; the processor  52 , the storage medium  54  and the external communication interface  51  are connected via a bus  53 . The processor  52  can be the microprocessor, the CPU, the DSP or the FPGA, and other electronic components with a processing function. 
     The storage medium  54  stores the computer executable instruction; the processor  52  performs any one of the following two solutions which can be implemented by the computer executable instruction stored in the storage medium  54 . 
     Solution 1:
         a symbol level DME interference result is obtained; and   a scheduling message is sent according to the obtained symbol level DME interference result or according to the obtained symbol level DME interference result and a PDSCH scheduling situation of a current subframe.       

     Solution 2:
         a scheduling message is received; wherein, the scheduling message is sent by a terminal according to a obtained symbol level DME interference result or according to the obtained symbol level DME interference result and a PDSCH scheduling situation of a current subframe; and   the subframe is scheduled according to the received scheduling message.       

     When being used for performing the solution 1, the device can serve as a part of the mobile terminal UE; when being used for performing the solution 2, the device can serve as a part of the base station, for example, as a part of the eNB. 
     The external communication interface  51  is a wireless communication interface preferably, for example, a transceiver antenna or a transceiver antenna array. 
     The above is only the preferred embodiments of the present disclosure and not intended to limit the scope of the claims of the present disclosure. It should be understood that any modification made according to the principle of the present disclosure falls within the scope of the claims of the present disclosure.