JP6818850B2 - User equipment, transmitter, receiving method, transmitting method and integrated circuit - Google Patents

Description

The present disclosure relates to the field of wireless communication, and more particularly to eNodeB (eNB), user equipment (UE: User Equipment), and wireless communication method for transmission interval time (TTI) indication.

Latency reduction is a theme in 3GPP, and the main method is to change the TTI length from, for example, 1 ms to 1 orthogonal frequency division multiplexing (OFDM) symbol, which significantly increases the transmission latency. Can be shortened.

According to one embodiment, which is not limited and is exemplary, a method for determining or instructing a candidate TTI for a physical channel is provided.

In the first general aspect of the present disclosure, the effective transmission interval time (TTI) for a physical channel in a subframe is determined based on the number of resource elements (REs) of each TTI in the subframe. Each TTI comprises a circuit that operates in such a manner and a receiver that operates to receive a physical channel within one or more of the valid TTIs by blind decoding some or all of the valid TTIs. , 1-7 Orthogonal Frequency Division Multiplexing (OFDM) symbols are provided.

In a second general aspect of the present disclosure, it operates to determine a valid transmit interval time (TTI) for a physical channel within a subframe based on the number of resource elements (RE) of each TTI within the subframe. Each TTI comprises a 1-7 Orthogonal Frequency Division Multiplexing (OFDM) symbol that operates to transmit a physical channel to a user device (UE) within one or more of the valid TTIs. Including, eNodeB (eNB) is provided.

In a third general aspect of the present disclosure, a circuit that operates to generate a bitmap indicating a candidate transmission interval time (TTI) for a physical channel in a subframe and the bitmap are radio resource control (RRC). Each TTI in a subframe comprises 1-7, with a transmitter operating to transmit in a layer or media access control (MAC) layer and to transmit a physical channel within one or more of the candidate TTIs. An eNodeB (eNB) is provided that includes orthogonal frequency division multiplex (OFDM) symbols and the size of the bitmap depends on the length of the TTI within the subframe.

In a fourth general aspect of the present disclosure, at the radio resource control (RRC) layer or media access control (MAC) layer, a bitmap indicating a candidate transmission interval time (TTI) for a physical channel in a subframe is received. The receiver comprises a receiver that operates to determine a candidate TTI based on a bitmap, and the receiver physically within one or more of the candidate TTIs by blindly decoding the candidate TTI. It also works to receive channels, each TTI in a subframe contains 1-7 orthogonal frequency division multiplexing (OFDM) symbols, and the size of the bitmap depends on the length of the TTI in the subframe. User equipment (UE) is provided.

In a fifth general aspect of the present disclosure, a wireless communication method performed by a user device (UE), wherein a valid transmission interval time (TTI) for a physical channel in the subframe is set for each in the subframe. It includes a step of determining based on the number of resource elements (REs) of the TTI and a step of receiving a physical channel within one or more of the valid TTIs by blind decoding some or all of the valid TTIs. , Each TTI is provided with a wireless communication method that includes 1-7 orthogonal frequency division multiplexing (OFDM) symbols.

In a sixth general aspect of the present disclosure, a wireless communication method performed by an eNodeB (eNB), each TTI within a subframe has a valid transmission interval time (TTI) for a physical channel within the subframe. Each TTI includes 1-7 orthogonal frequency divisions, including a step of determining based on the number of resource elements (REs) in the TTI and a step of transmitting a physical channel to the user equipment (UE) within one or more of the valid TTIs. A wireless communication method is provided that includes a multiplex (OFDM) symbol.

In a seventh general aspect of the present disclosure, a wireless communication method performed by an eNodeB (eNB), the step of generating a bitmap showing a candidate transmission interval time (TTI) for a physical channel within a subframe. And each TTI in the subframe, including the step of transmitting the bitmap in the radio resource control (RRC) layer or the media access control (MAC) layer, and the step of transmitting the physical channel within one or more of the candidate TTIs. Provides a wireless communication method that includes 1-7 orthogonal frequency division multiplex (OFDM) symbols and the size of the bitmap depends on the length of the TTI within the subframe.

Eighth general aspect of the present disclosure is a wireless communication method performed by a user device (UE), the physical within a subframe in the wireless resource control (RRC) layer or media access control (MAC) layer. Within one or more of the candidate TTIs by receiving a bitmap indicating the candidate transmission interval time (TTI) for the channel, determining the candidate TTI based on the bitmap, and blindly decoding the candidate TTI. Each TTI in a subframe contains 1-7 Orthogonal Frequency Division Multiplexing (OFDM) symbols, including the step of receiving a physical channel, and the size of the bitmap depends on the length of the TTI in the subframe. A wireless communication method is provided.

It should be noted that general or specific embodiments may be implemented as systems, methods, integrated circuits, computer programs, storage media, or any combination thereof.

Further benefits and advantages of the disclosed embodiments will become apparent from the specification and drawings. Benefits and / or benefits may be obtained individually by various embodiments and features of the specification and drawings, all of which are provided to obtain one or more of these benefits and / or benefits. There is no need.

The aforementioned and other features of the present disclosure are made more completely apparent in the context of the accompanying drawings by the following statements and the appended claims. Understanding that these drawings only depict some embodiments of the present disclosure and therefore should not be considered to limit their scope, the present disclosure uses the accompanying drawings. Then, it is described in more specific and detailed manner.

Some examples of TTI length reduction are shown schematically. Candidate TTIs for transmitting EPDCCH within subframes are outlined. The block diagram of the eNB according to the embodiment of the present disclosure is shown schematically. A flowchart of a wireless communication method executed by eNB according to an embodiment of the present disclosure is shown. The block diagram of the UE according to the embodiment of the present disclosure is shown schematically. A flowchart of a wireless communication method executed by a UE according to an embodiment of the present disclosure is shown. The block diagram of the UE according to the embodiment of the present disclosure is shown schematically. The reference signal estimation in one example is shown schematically. A flowchart of a wireless communication method executed by a UE according to an embodiment of the present disclosure is shown. A flowchart of a wireless communication method executed by eNB according to an embodiment of the present disclosure is shown.

The detailed description below refers to the accompanying drawings and is incorporated as part of the description. In drawings, similar signs usually identify similar components, unless the context dictates otherwise. It is readily understood that aspects of this disclosure can be arranged, replaced, mixed, and designed in a wide variety of different configurations, all of which are expressly expected and form part of this disclosure.

Latency reduction is one theme of 3GPP RAN1, and the main method is to reduce the TTI length from, for example, 1 ms to 1 to 7 OFDM symbols, and as a result, the transfer latency can be reduced. FIG. 1 shows some examples of shortening the TTI length. In FIG. 1, from top to bottom, the first plot shows the normal TTI, i.e. the TTI with a TTI length of 1 subframe, and the second plot shows the TTI with a length of 1 slot (7 OFDM symbols). The third plot shows the TTI of a 4 or 3 OFDM symbol of length (eg, the 1st and 3rd TTIs in a subframe are 4OFDM symbols and the 2nd and 4th TTIs are 3OFDM symbols). Shown, the fourth plot shows the TTI of a 1 OFDM symbol of length.

Normally, one physical channel, such as EPDCCH or PDSCH, is transmitted within 1 TTI, regardless of how long the TTI is. If the TTI length is a 1OFDM symbol, the physical channel will be transmitted within the 1OFDM symbol, and if the TTI length is a 7OFDM symbol, the physical channel will be transmitted within the 7OFDM symbol. Note that TTI is a general terminology that can be used in any channel transmission. For example, the physical channels of the present disclosure can refer to any downlink channel such as EPDCCH and PDSCH.

Taking EPDCCH as an example, assuming that a shortened 1 TTI less than one subframe transmits one EPDCCH, assuming that all TTIs in a subframe may transmit EPDCCH is a sub. This is not possible because it significantly increases the blind decoding (BD) time of the UE within the frame and increases the complexity of the UE. Therefore, we propose to configure only some TTIs in the subframe to be candidates for transmitting EPDCCH. FIG. 2 schematically shows a candidate TTI for transmitting EPDCCH within a subframe, the length of the TTI being 1 OFDM symbol. In the example of FIG. 2, the EPDCCH can only be transmitted within the candidate TTI, and the UE only needs to blindly decode the candidate TTI. In this way, the BD time can be shortened.

In order for the above mechanism, in which the physical channel is transmitted only within the candidate TTI for the physical channel in the subframe to work, the UE needs to know which TTI is the candidate TTI for the physical channel.

In one embodiment of the present disclosure, a 14-bit bitmap can be used in the radio resource control (RRC) layer or media access control (MAC) layer to indicate a candidate TTI to each UE. This 14-bit bitmap can be used for all possible TTI lengths. For a TTI of 1 OFDM symbol in length, each bit in the 14-bit bitmap indicates whether one TTI is a candidate TTI, for example, bit "1" means candidate and bit "0" is non-candidate. Means. For long TTIs, 2 bits or more can be used to indicate the state of one TTI, for example, for TTIs with a length of 2 OFDM symbols, 2 bits to indicate the state of one TTI. Can be used.

In the above embodiment, a unified 14-bit bitmap is used for all possible TTI lengths, which can lead to relatively large overhead. In another embodiment, the size of the bitmap to indicate a candidate TTI within a subframe can depend on the length of the TTI within the subframe. The number of TTIs in a subframe can be calculated based on the length of the TTI, and the number of bits in the bitmap can be matched (eg, equalized) to the number of TTIs.

For example, if all TTI lengths are the same in a subframe and the TTI length is 1 OFDM symbol, then the number of TTIs in a regular subframe is 14, and a 14-bit bitmap can be used. If the TTI length is a 7 OFDM symbol, the number of TTIs in the regular subframe is 2, and a 2-bit bitmap can be used. In special cases, if the TTI length is not exactly the common divisor of 14 (the number of OFDM symbols in a regular subframe), then at least two TTIs in the subframe can be arranged to overlap each other or sub Some OFDM symbols in the frame (eg, in the last m OFDM symbols, where m is the remainder of 14 divided by the TTI length) can be prevented from being assigned to the TTI. For example, if the TTI length is 4, the first TTI and the second TTI overlap with one OFDM symbol (ie, the OFDM symbol at the end of the first TTI is the OFDM symbol at the beginning of the second TTI. And to overlap the 3rd TTI and the 4th TTI with one OFDM symbol (that is, the OFDM symbol at the end of the 3rd TTI becomes the OFDM symbol at the beginning of the 4th TTI). This allows four TTIs to be present in the subframe, so a 4-bit bitmap can be used, or else the last two OFDMs in the subframe can be assigned to any TTI. By not having it, three TTIs can be present in the subframe, so a 3-bit bitmap can be used.

In another example, in order to take full advantage of the OFDM symbols in the subframe, make sure that the TTI lengths are not all the same within the subframe, as in the TTI arrangement shown in the third plot of FIG. Here, the lengths of the first TTI and the third TTI in the subframe are 4 OFDM symbols, and the lengths of the second TTI and the fourth TTI are 3 OFDM symbols. In this case, the number of TTIs can be counted based on the unique TTI placement within the subframe. For the example shown in the third plot of FIG. 2, the number of TTIs in the subframe is 4, and a 4-bit bitmap can be used.

Based on the concept of using different bitmaps for different subframes with different TTI lengths or TTI numbers, according to one embodiment of the present disclosure, a block diagram of the eNB 300 according to one embodiment of the present disclosure is schematically illustrated. The eNB 300 shown in FIG. 3 is provided. The eNB 300 is to transmit the bitmap to the UE in circuit 301, RRC layer or MAC layer which operates to generate a bitmap indicating a candidate TTI (ie, one or more TTIs) for the physical channel in the subframe. And with a transmitter 302 that operates to transmit a physical channel to the UE within one or more of the candidate TTIs. Each TTI in the subframe contains 1-7 OFDM symbols, and the size of the bitmap depends on the length of the TTI in the subframe. An exemplary method of determining the size of the bitmap can be referred to above for determining the number of TTIs and the size of the bitmap.

In this embodiment, the eNB 300 transmits to the UE a bitmap whose size depends on the length of the TTI in the subframe at the RRC layer or the MAC layer in order for the UE to determine the candidate TTI in the subframe. Therefore, the bitmap size can be optimized and the overhead can be reduced. In the present disclosure, one physical channel (EPDCCH, PDSCH, etc.) can be transmitted within one or more candidate TTIs. When one physical channel is transmitted in multiple TTIs, the UE can decode the multiple TTIs carrying the physical channels together.

In one embodiment, the length of TTI within a subframe can be UE-specific, in other words, not all UEs are configured with the same TTI length. As an example, the length of the TTI in the subframe depends on the coverage status of the UE. For example, for a UE at the cell end where the radio status is relatively poor, the channel estimation capability will be relatively poor, so it is rational to set more OFDM symbols as the TTI length, and the radio status is compared. For a good, cell-centered UE, the channel estimation ability will be relatively good, so it is reasonable to set a shorter TTI length (eg, 1 OFDM symbol). The eNB can determine the coverage status of the UE from the received uplink signal or reference signal received power (RSRP: Reference Signal Received Power) report.

In one embodiment of the eNB 300, the special subframe or subframe can use the same bitmap as the regular subframe. In the present disclosure, "special subframes" are as defined in specification 3GPP TS 36.211 for TDD, and "partial subframes" are subframes as defined in specification 3GPP TS 36.211 for unlicensed carrier access. A subframe in which transmission begins in the second slot of the frame. The bitmap size of the regular subframe can be determined as described above. If the subframe is a special subframe or subframe, the n bits of the bitmap (eg the first n bits) are used to indicate a candidate TTI, where n is the TTI within the special subframe or subframe. Depends on the number. For example, in the case of the special subframe configuration 0 in which the number of DwPTS symbols is 3, when the TTI length is 4 OFDM symbols, the bitmap "1100" causes the first and second TTIs of the special subframe and the regular subframe to be set. It can mean that it is a candidate TTI. Alternatively, a special bitmap can be used to indicate which TTI in the special subframe or subframe is the candidate TTI, and the size of the special bitmap is within the special subframe or subframe. It can be determined based on the number of TTIs.

Further, as shown in FIG. 3, the eNB 300 according to the present disclosure is a CPU (Central Processing Unit: Central Processing Unit) 310 for executing a related program that processes various data and control operations of each unit in the eNB 300. ROM (Read Only Memory) 313 for storing various programs required to execute various processes and controls by the CPU 310, intermediate generated temporarily in the process and control procedures by the CPU 310. A RAM (random access memory: Random Access Memory) 315 for storing data and / or a storage unit 317 for storing various programs, data, and the like may be optionally provided.

The circuit 301 and the transmission unit 302, CPU 310, ROM 313, RAM 315 and / or storage unit 317 and the like may be connected to each other via data and / or command bus 320 to transmit signals to each other.

Each of the above components does not limit the scope of this disclosure. According to one embodiment of the present disclosure, the functions of the circuit 301 and the transmitter 302 may be performed by hardware, and the CPU 310, ROM 313, RAM 315 and / or storage unit 317 are unnecessary. May be good. Alternatively, the functions of the circuit 301 and the transmitter 302 may be performed by functional software in combination with the CPU 310, ROM 313, RAM 315 and / or storage unit 317 and the like.

FIG. 4 shows a flowchart of a wireless communication method 400 executed by an eNB (for example, an eNB 300) according to an embodiment of the present disclosure. The wireless communication method 400 includes step 401 for generating a bitmap indicating a candidate TTI for a physical channel in a subframe, step 402 for transmitting the bitmap to the UE at the RRC layer or the MAC layer, and one or more of the candidate TTIs. It can include a step 403 of transmitting a physical channel to the UE within. Each TTI in the subframe contains 1-7 OFDM symbols, and the size of the bitmap depends on the length of the TTI in the subframe. The above details and advantages of the eNB 300 can also be applied to the wireless communication method 400.

Accordingly, according to the embodiments of the present disclosure, a UE and a wireless communication method performed by the UE are also provided.

FIG. 5 schematically shows a block diagram of the UE 500 according to the embodiment of the present disclosure. The UE 500 operates in the RRC layer or the MAC layer to receive a bitmap indicating a candidate TTI for a physical channel in a subframe, and a receiver 501 that operates to determine the candidate TTI based on the bitmap. A circuit 502 can be provided, the receiver also operates to receive a physical channel within one or more of the candidate TTIs by blind decoding the candidate TTIs, with each TTI in the subframe being one. Includes ~ 7 Orthogonal Frequency Division Multiplexing (OFDM) symbols, and the size of the bitmap depends on the length of the TTI within the subframe. In an embodiment, the UE 500 can obtain information about the candidate TTI based on a bitmap, and thus only blindly decodes the candidate TTI to receive a physical channel transmitted within one or more of the candidate TTIs. Is.

The UE 500 according to the present disclosure is a CPU (Central Processing Unit) 510 for executing related programs for processing various data and control operations of each unit in the UE 500, in order to execute various processes and controls by the CPU 510. ROM (read-only memory) 513 for storing various required programs, RAM (random access memory) 515 for storing intermediate data temporarily generated by the CPU 510 in process and control procedures, and / or A storage unit 517 for storing various programs, data, and the like may be optionally provided. The receiver 501, circuit 502, CPU 510, ROM 513, RAM 515 and / or storage unit 517 and the like may be connected to each other via data and / or command bus 520 to transmit signals to each other.

Each of the above components does not limit the scope of this disclosure. According to one embodiment of the present disclosure, the functions of the receiver 501 and the circuit 502 may be performed by hardware, and the CPU 510, ROM 513, RAM 515 and / or storage unit 517 may be unnecessary. May be good. Alternatively, the functions of the receiver 501 and the circuit 502 may be performed by functional software in combination with the CPU 510, ROM 513, RAM 515 and / or storage unit 517 and the like.

FIG. 6 shows a flowchart of a wireless communication method 600 executed by a UE (for example, UE 500) according to an embodiment of the present disclosure. The wireless communication method 600 has, in the RRC layer or the MAC layer, a step 601 of receiving a bitmap indicating a candidate TTI for a physical channel in a subframe, a step 602 of determining a candidate TTI based on the bitmap, and a candidate TTI. Can include step 603 of receiving a physical channel within one or more of the candidate TTIs by blind decoding, each TTI in the subframe containing 1-7 OFDM symbols, and the size of the bitmap. It depends on the length of the TTI in the subframe.

Unless otherwise specified by the context, the above details and merits of the eNB side can also be applied to the UE side.

In another embodiment of the present disclosure, in order to determine a candidate TTI for transmitting a physical channel within a subframe, a valid TTI for the physical channel is determined based on the RE number of each TTI within the subframe. .. In the present disclosure, "effective TTI" for a physical channel means a TTI capable of transmitting a physical channel. For example, in the case where one TTI transmits one physical channel, if the RE number of the TTI is sufficient to transmit the physical channel, the TTI is a valid TTI. When a physical channel is configured to be able to transmit within multiple TTIs, the multiple TTIs are valid TTIs if the total RE number of the multiple TTIs is sufficient to transmit the physical channels. Is. Since the physical channel can only be transmitted within a valid TTI, the UE only needs to blindly decode the valid TTI in order to receive the physical channel. In one example, all valid TTIs are considered candidate TTIs to transmit all physical channels and there is no bitmap to further indicate the candidates, so the UE needs to blindly decode all valid TTIs. In another example, there is a bitmap applied to a valid TTI to further indicate which of the valid TTIs is a candidate TTI for the physical channel. In either example, the signaling overhead can be reduced. Specifically, for the latter example, the size of the bitmap can be reduced because the bitmap can be applied only to valid TTIs rather than to all TTIs in the subframe.

Based on the concept of determining a valid TTI based on the RE number of each TTI in a subframe, according to one embodiment of the present disclosure, a block diagram of the UE 700 according to one embodiment of the present disclosure is schematically shown. The UE 700 shown in FIG. 7 is provided. The UE 700 blindly decodes some or all of the valid TTIs with circuit 701 that operates to determine the valid TTIs for the physical channels in the subframe based on the RE number of each TTI in the subframe. A receiver 702 that operates to receive a physical channel within one or more of the valid TTIs can be provided, each TTI containing 1-7 OFDM symbols. In the embodiment, the UE can obtain information about valid TTIs based on the RE number of each TTI, so it is only necessary to blindly decode the valid TTIs, not all the TTIs in the subframe. Is. Unless otherwise specified by the context, the above description of FIG. 5 can be applied to the UE 700 of FIG.

Considering the EPDCCH as a physical channel, the reference signal configuration (eg, CSI-RS degradation behavior, periodicity, CRS port number and PDCCH configuration) and MBSFN configuration affect the number of REs in the TTI for transmitting EPDCCH. Become. As an example, the following assumptions can be made.

The DCI size is 32 bits (including CRC), QPSK and 1/3 code rate are adopted, and the number of REs required to transmit such DCI is 32 × 3/2 = 48.

4PRB is assigned for the shortened TTI in the subframe, and the TTI length is 1 OFDM symbol.

-The reference signal estimation is as shown in FIG. 8 which schematically shows the reference signal estimation in one example. In FIG. 8, two CRS ports, 24 DMRS REs, 8 ports of CSI-RS and 1 OFDM symbol PDCCH are assumed in the PRB. At OFDM symbol (or TTI) 0, the number of REs available for EPDCCH is zero because PDCCH occupies the entire PRB. For OFDM symbols (or TTIs) 5, 6, 12 and 13, the number of REs available for EPDCCH is 6 because the number of REs for DMRS in the PRB is 6. The number of REs available for another OFDM symbol can be calculated in a similar manner.

Based on the above assumptions, the number of REs in each TTI of one subframe can be determined as shown in Table 1. Only TTIs (or OFDM symbols) 1, 2, 3 and 8 are valid for EPDCCH, as the number of REs required to transmit the DCI is 48.

In one embodiment, all valid TTIs are considered candidate TTIs and the UE 700 blindly decodes all valid TTIs. In the above example shown in Table 1, four valid TTIs can be considered as candidate TTIs for EPDCCH.

Alternatively, in another embodiment, the eNB may transmit a bitmap applied to the valid TTI to further indicate which of the valid TTIs is the candidate TTI for the physical channel. .. Accordingly, the receiver 702 can further act to receive a bitmap showing candidate TTIs for the physical channel of the valid TTIs at the RRC or MAC layer to transmit the physical channels. One or more of the valid TTIs of the are in the candidate TTI, and the receiver 702 can act to blindly decode the candidate TTI when it receives the physical channel. Here, since the bitmap can only be applied to valid TTIs, the size of the bitmap can be equal to the number of valid TTIs in the subframe, so that the size of the bitmap is sub. It can be smaller than the bitmap that applies to all TTIs in the frame. For the above example shown in Table 1, a 4-bit bitmap can be used to indicate which of the four valid TTIs is the candidate TTI for EPDCCH. Alternatively, the size of the bitmap can be equal to the maximum number of valid TTIs in each subframe available to the UE. There are different types of subframes, for example MBSFN (Multicast Broadcast Single Frequency Network) subframes and non-MBSFN subframes, and some RSs like CSI-RS are in every subframe. It does not have to exist. Therefore, different types of subframes can have different situations regarding the number of valid TTIs. For the example shown in FIG. 8, CSI-RS may not be present in some subframes, so that TTIs (OFDM symbols) 9 and 10 are valid for EPDCCH in some subframes. Can be TTI. Therefore, the same bitmap for different types of subframes (eg, those with CSI-RS in OFDM symbols 9 and 10 and those without CSI-RS in OFDM symbols 9 and 10 shown in FIG. 8). To use, size the bitmap to the maximum size suitable for all types of subframes, i.e. equal to the maximum number of valid TTIs in each subframe available to the UE. can do. In the above example shown in FIG. 8 and Table 1, a 6-bit bitmap can be used to represent the symbols (TTI) 1, 2, 3, 8, 9 and 10. For subframes with CSI-RS, the bits in the bitmap for symbols 9 and 10 are not valid.

Normally, one physical channel is only transmitted within one TTI. However, if only one physical channel is transmitted within one TTI, it is possible that there are too few valid TTIs in the subframe. Therefore, as proposed in the present disclosure, multiple TTIs can be used to transmit one physical channel, such as EPDCCH. In the case where the RE number of each individual TTI in the set of TTIs in the subframe is not sufficient to transmit the physical channel, the set if the total RE number of the set of TTIs is sufficient to transmit the physical channel. A set of TTIs can be determined to be valid, a set of TTIs can be used in combination to transmit a physical channel, and the receiver 702 can decode the set of TTIs together. For example, assuming that two consecutive TTIs can transmit one EPDCCH, in the examples shown in FIG. 8 and Table 1, invalid TTI0, 4 when the EPDCCH can only be transmitted within one TTI. Of 5, 6, 7, 9, 10, 11, 12 and 13, as shown in Table 2, the combinations of TTI4 and 5, 6 and 7, and 9 and 10 also have REs in which each combination exceeds 48. Therefore, it can be determined to be effective. As a result, the shortened TTI transmission capacity can be increased. In one embodiment, EPDCCH spanning 2 TTIs can only be transmitted within a TTI that was invalid when the EPDCCH was transmitted within only one TTI.

In one embodiment of the present disclosure, a wireless communication method 900 executed by the UE 700 is also provided. FIG. 9 shows a flowchart of the wireless communication method 900 executed by the UE according to the embodiment of the present disclosure. The radio communication method 900 blindly decodes some or all of the valid TTIs with step 901, which determines the valid TTIs for the physical channels in the subframe based on the RE number of each TTI in the subframe. This can include step 902 of receiving a physical channel within one or more of the valid TTIs, each TTI containing 1-7 OFDM symbols. The details and advantages of the UE 700 described above can also be applied to the wireless communication method 900.

On the eNB side, according to the embodiments of the present disclosure, the eNB and the wireless communication method executed by the eNB are provided.

FIG. 10 shows a flowchart of the wireless communication method 1000 executed by the eNB according to the embodiment of the present disclosure. The wireless communication method 1000 determines a valid TTI for a physical channel in a subframe based on the RE number of each TTI in the subframe, and steps 1001 to transfer the physical channel to the UE within one or more of the valid TTIs. Each TTI may include 1-7 OFDM symbols, which may include steps 1002 to transmit. Optionally, the method 1000 can also include a step of transmitting a bitmap indicating a candidate TTI for the physical channel of the valid TTIs to the UE at the RRC or MAC layer, where the size of the bitmap is within the subframe. Equal to the maximum number of valid TTIs in, or the maximum number of valid TTIs in each subframe available to the UE, and one or more of the valid TTIs for transmitting a physical channel are candidates. It's in TTI.

According to one embodiment of the present disclosure, an eNB for performing the above method 1000 is also provided, where the eNB provides a valid TTI for the physical channel in the subframe based on the RE number of each TTI in the subframe. Each TTI may include a circuit that operates to determine and a transmitter that operates to transmit a physical channel to the UE within one or more of the valid TTIs, each TTI containing 1-7 OFDM symbols. Optionally, the transmitter can further act to transmit a bitmap indicating a candidate TTI for the physical channel of the valid TTIs to the UE at the RRC or MAC layer, and the size of the bitmap is sub. Equal to the maximum number of valid TTIs in a frame, or the number of valid TTIs in each subframe available to the UE, and one or more of the valid TTIs for transmitting a physical channel. , Among the candidate TTIs. The block diagram of the eNB in this embodiment can refer to the structure shown in FIG.

Unless otherwise specified by the context, the above details and benefits for the UE side can also be applied to the eNB side.

The present disclosure may be realized by software, hardware, or software linked to the hardware. Each functional block used in the description of each of the above embodiments can be realized by an LSI as an integrated circuit, and each process described in each embodiment may be controlled by an LSI. They may be individually formed as chips, or one chip may be formed to include some or all functional blocks. They may include data inputs and outputs coupled to them. Here, the LSI may be referred to as an IC, a system LSI, a super LSI, or an ultra LSI depending on the degree of integration. However, the technique for mounting the integrated circuit is not limited to the LSI, and may be realized by using a dedicated circuit or a general-purpose processor. It also uses an FPGA (Field Programmable Gate Array) that can be programmed after the LSI is manufactured, or a reconfigurable processor that can reconfigure the connections and settings of circuit cells located within the LSI. You may.

It should be noted that this disclosure is intended to be modified or modified by one of ordinary skill in the art based on the description and known techniques presented herein without departing from the content and scope of this disclosure. , Such changes and applications are included in the scope of claiming protection. Further, the components of the above-described embodiment may be arbitrarily combined as long as the contents of the present disclosure are not deviated.

According to the embodiments of the present disclosure, at least the following subjects can be provided.

1. 1. A circuit that operates to determine the effective transmission interval time (TTI) for a physical channel in a subframe based on the number of resource elements (REs) of each TTI in the subframe. ,
A receiver that operates to receive the physical channel within one or more of the valid TTIs by blind decoding some or all of the valid TTIs.
Each TTI contains 1-7 Orthogonal Frequency Division Multiplexing (OFDM) symbols.
User equipment (UE).

2. 2. The receiver receives a bitmap showing a candidate TTI for the physical channel among the valid TTIs in a radio resource control (RRC: radio resource control) layer or a media access control (MAC: media access control) layer. And the size of the bitmap is the largest of the number of valid TTIs in the subframe or the number of valid TTIs in each subframe available to the UE. equally,
The one or more of the valid TTIs for transmitting the physical channel are in the candidate TTI so that the receiver blindly decodes the candidate TTI when receiving the physical channel. Operate,
The user device according to 1.

3. 3. The same bitmap is used for different types of subframes,
The size of the bitmap is equal to the maximum number of valid TTIs in each subframe available to the UE.
The user device according to 2.

4. The receiver acts to blindly decode all of the valid TTIs when receiving the physical channel.
The user device according to 1.

5. In cases where the RE number of each individual TTI in a set of TTIs is not sufficient to transmit the physical channel, if the total RE number of the TTI in the set is sufficient to transmit the physical channel. The circuit further operates to determine that the set of TTIs in the subframe is valid, and the set of TTIs are used in combination to transmit the physical channel.
The user device according to 1.

6. A circuit that operates to determine the effective transmission interval time (TTI) for a physical channel in a subframe based on the number of resource elements (REs) of each TTI in the subframe. ,
A transmitter that operates to transmit the physical channel to a user device (UE) within one or more of the valid TTIs.
Each TTI contains 1-7 Orthogonal Frequency Division Multiplexing (OFDM) symbols.
eNodeB (eNB).

7. The transmitter displays a bitmap showing a candidate TTI for the physical channel among the valid TTIs in the radio resource control (RRC) layer or media access control (MAC) layer of the UE. Further acting to send to, the size of the bitmap is the maximum of the number of valid TTIs in the subframe, or the number of valid TTIs in each subframe available to the UE. Equal to
The one or more of the valid TTIs for transmitting the physical channel are among the candidate TTIs.
6. The eNodeB according to 6.

8. The same bitmap is used for different types of subframes,
The size of the bitmap is equal to the maximum number of valid TTIs in each subframe available to the UE.
7. The eNodeB according to 7.

9. The transmitter operates to transmit the physical channel within one or more of the valid TTIs by regarding all of the valid TTIs as candidate TTIs for the physical channel.
6. The eNodeB according to 6.

10. In cases where the RE number of each individual TTI in a set of TTIs is not sufficient to transmit the physical channel, if the total RE number of the TTI in the set is sufficient to transmit the physical channel. The circuit further operates to determine that the set of TTIs in the subframe is valid, and the set of TTIs are used in combination to transmit the physical channel.
6. The eNodeB according to 6.

11. A circuit that operates to generate a bitmap showing the candidate transmission interval time (TTI: transition time interval) for a physical channel in a subframe.
To transmit the bitmap in a radio resource control (RRC) layer or a medium access control (MAC) layer, and to transmit the physical channel within one or more of the candidate TTIs. Equipped with a transmitter that works with
Each TTI in the subframe comprises a 1-7 orthogonal frequency division multiplexing (OFDM) symbol, the size of the bitmap depends on the length of the TTI in the subframe.
eNodeB (eNB).

12. The length of the TTI within the subframe is unique to the user equipment (UE).
11. The eNodeB according to 11.

13. The length of the TTI within the subframe depends on the coverage status of the UE.
12. The eNodeB according to 12.

14. The lengths of the TTIs in the subframe are all the same,
If the length of the TTI is not exactly the common divisor of 14, then at least two TTIs in the subframe are arranged to overlap each other, or some OFDM symbols in the subframe are said to be Not assigned to TTI,
11. The eNodeB according to 11.

15. If the subframe is a special subframe or subframe, n bits of the bitmap are used to indicate the candidate TTI, where n depends on the number of TTIs in the special subframe or subframe. To do
11. The eNodeB according to 11.

16. Receives a bitmap indicating the candidate transmission interval time (TTI) for a physical channel in a subframe at the radio resource control (RRC) layer or the medium access control (MAC) layer. With a receiver that works to
A circuit that operates to determine the candidate TTI based on the bitmap.
The receiver also operates to receive the physical channel within one or more of the candidate TTIs by blind decoding the candidate TTIs.
Each TTI in the subframe comprises a 1-7 orthogonal frequency division multiplexing (OFDM) symbol, the size of the bitmap depends on the length of the TTI in the subframe.
User equipment (UE).

17. The length of the TTI within the subframe is unique to the user equipment (UE).
16. The user device according to 16.

18. The length of the TTI within the subframe depends on the coverage status of the UE.
17. The user device according to 17.

19. The lengths of the TTIs in the subframe are all the same,
If the length of the TTI is not exactly the common divisor of 14, then at least two TTIs in the subframe are arranged to overlap each other, or some OFDM symbols in the subframe are said to be Not assigned to TTI,
16. The user device according to 16.

20. If the subframe is a special subframe or subframe, n bits of the bitmap are used to indicate the candidate TTI, where n depends on the number of TTIs in the special subframe or subframe. To do
16. The user device according to 16.

21. A wireless communication method executed by a user device (UE).
A step of determining a valid transmission interval time (TTI: transition time interval) for a physical channel in a subframe based on the number of resource elements (REs) of each TTI in the subframe.
Including the step of receiving the physical channel within one or more of the valid TTIs by blind decoding some or all of the valid TTIs.
Each TTI contains 1-7 Orthogonal Frequency Division Multiplexing (OFDM) symbols.
Wireless communication method.

22. It further comprises the step of receiving a bitmap showing a candidate TTI for the physical channel of the valid TTIs at the radio resource control (RRC) layer or the media access control (MAC) layer.
The size of the bitmap is equal to the maximum of the number of valid TTIs in the subframe or the number of valid TTIs in each subframe available to the UE.
The one or more of the valid TTIs for transmitting the physical channel are among the candidate TTIs, which are blindly decoded when the physical channel is received.
21. The wireless communication method.

23. The same bitmap is used for different types of subframes,
The size of the bitmap is equal to the maximum number of valid TTIs in each subframe available to the UE.
22. The wireless communication method.

24. When receiving the physical channel, all of the valid TTIs are blind decoded.
21. The wireless communication method.

25. In cases where the RE number of each individual TTI in a set of TTIs is not sufficient to transmit the physical channel, if the total RE number of the TTI in the set is sufficient to transmit the physical channel. Further including a step of determining that the set of TTIs in the subframe is valid, the set of TTIs are used in combination to transmit the physical channel.
21. The wireless communication method.

26. A wireless communication method executed by eNodeB (eNB).
A step of determining a valid transmission interval time (TTI: transition time interval) for a physical channel in a subframe based on the number of resource elements (REs) of each TTI in the subframe.
Including the step of transmitting the physical channel to the user equipment (UE) within one or more of the valid TTIs.
Each TTI contains 1-7 Orthogonal Frequency Division Multiplexing (OFDM) symbols.
Wireless communication method.

27. A step of transmitting a bitmap showing a candidate TTI for the physical channel among the valid TTIs to the UE in a radio resource control (RRC) layer or a medium access control (MAC) layer. Including more
The size of the bitmap is equal to the maximum of the number of valid TTIs in the subframe or the number of valid TTIs in each subframe available to the UE.
The one or more of the valid TTIs for transmitting the physical channel are among the candidate TTIs.
The wireless communication method according to 26.

28. The same bitmap is used for different types of subframes,
The size of the bitmap is equal to the maximum number of valid TTIs in each subframe available to the UE.
27. The wireless communication method.

29. The physical channel is transmitted within one or more of the valid TTIs by considering all of the valid TTIs as candidate TTIs for the physical channel.
The wireless communication method according to 26.

30. In cases where the RE number of each individual TTI in a set of TTIs is not sufficient to transmit the physical channel, if the total RE number of the TTI in the set is sufficient to transmit the physical channel. Further including a step of determining that the set of TTIs in the subframe is valid, the set of TTIs are used in combination to transmit the physical channel.
The wireless communication method according to 26.

31. A wireless communication method executed by eNodeB (eNB).
A step to generate a bitmap showing the candidate transmission interval time (TTI: transition time interval) for the physical channel in the subframe, and
A step of transmitting the bitmap in a radio resource control (RRC: radio resource control) layer or a media access control (MAC) layer, and a step of transmitting the bitmap.
Including the step of transmitting the physical channel within one or more of the candidate TTIs.
Each TTI in the subframe comprises a 1-7 orthogonal frequency division multiplexing (OFDM) symbol, the size of the bitmap depends on the length of the TTI in the subframe.
Wireless communication method.

32. The length of the TTI within the subframe is unique to the user equipment (UE).
31. The wireless communication method.

33. The length of the TTI within the subframe depends on the coverage status of the UE.
32. The wireless communication method.

34. The lengths of the TTIs in the subframe are all the same,
If the length of the TTI is not exactly the common divisor of 14, then at least two TTIs in the subframe are arranged to overlap each other, or some OFDM symbols in the subframe are said to be Not assigned to TTI,
31. The wireless communication method.

35. If the subframe is a special subframe or subframe, n bits of the bitmap are used to indicate the candidate TTI, where n depends on the number of TTIs in the special subframe or subframe. To do
31. The wireless communication method.

36. A wireless communication method executed by a user device (UE).
Receives a bitmap indicating the candidate transmission interval time (TTI) for a physical channel in a subframe at the radio resource control (RRC) layer or the medium access control (MAC) layer. Steps to do and
The step of determining the candidate TTI based on the bitmap, and
Includes the step of receiving the physical channel within one or more of the candidate TTIs by blind decoding the candidate TTIs.
Each TTI in the subframe comprises a 1-7 orthogonal frequency division multiplexing (OFDM) symbol, the size of the bitmap depends on the length of the TTI in the subframe.
Wireless communication method.

37. The length of the TTI within the subframe is unique to the user equipment (UE).
36. The wireless communication method.

38. The length of the TTI within the subframe depends on the coverage status of the UE.
37. The wireless communication method.

39. The lengths of the TTIs in the subframe are all the same,
If the length of the TTI is not exactly the common divisor of 14, then at least two TTIs in the subframe are arranged to overlap each other, or some OFDM symbols in the subframe are said to be Not assigned to TTI,
36. The wireless communication method.

40. If the subframe is a special subframe or subframe, n bits of the bitmap are used to indicate the candidate TTI, where n depends on the number of TTIs in the special subframe or subframe. To do
36. The wireless communication method.

Also, according to the embodiments of the present disclosure, it is possible to provide an integrated circuit including a module for performing a step in each of the above communication methods. Further, according to an embodiment of the present disclosure, when executed on a computing device, a computer-readable computer program containing program code for executing each of the above communication method steps is stored therein. A storage medium can also be provided.

Claims (20)

A one or more transmission time intervals is the symbol for the physical channel, 14 among the plurality of transmission time intervals that can be configured in a symbol, the reception unit for receiving a bitmap indicating one or more candidate When,
A circuit that blindly decodes the physical channel in the candidate based on the bitmap.
Has a user device. The length of the transmission time interval is variable, and the size of the bitmap is uniform for all of the different lengths of the transmission time interval.
The user device according to claim 1. The size of the bitmap is equal to the maximum number of the plurality of transmission time intervals configurable in the 14 symbols.
The user device according to claim 1. The size of the bitmap is 14 bits.
The user device according to claim 1. The receiving unit receives the bitmap in a radio resource control (RRC: radio resource control) layer or a media access control (MAC: media access control) layer.
The user device according to claim 1. The length of the transmission time interval is unique to the user device.
The user device according to claim 1. The length of the transmission time interval depends on the coverage status of the user device.
The user device according to claim 1. The transmission time interval candidate is based on the reference signal configuration.
The user device according to claim 1. A one or more transmission time intervals is the symbol for the physical channel, 14 among the plurality of possible configurations of the transmission time interval in a symbol, a one or more candidate user equipment the physical A circuit that generates a bitmap showing the candidate for blind decoding of the channel,
A transmitter that transmits the bitmap to the user device,
Has a transmitter. The length of the transmission time interval is variable, and the size of the bitmap is uniform for all of the different lengths of the transmission time interval.
The transmitting device according to claim 9. The size of the bitmap is equal to the maximum number of the plurality of transmission time intervals configurable in the 14 symbols.
The transmitting device according to claim 9. The size of the bitmap is 14 bits.
The transmitting device according to claim 9. The transmitting unit transmits the bitmap in a radio resource control (RRC: radio resource control) layer or a media access control (MAC) layer.
The transmitting device according to claim 9. The length of the transmission time interval is unique to the user device.
The transmitting device according to claim 9. The length of the transmission time interval depends on the coverage status of the user device.
The transmitting device according to claim 9. The transmission time interval candidate is based on the reference signal configuration.
The transmitting device according to claim 9. The receiver receives a bitmap indicating a transmission time interval that is one or more symbols for a physical channel and that indicates one or more candidates among the plurality of transmission time intervals that can be configured in 14 symbols. And the process to do
A step in which the circuit blindly decodes the physical channel in the candidate based on the bitmap.
Receiving method. The circuit is a transmission time interval that is one or more symbols for a physical channel, and is one or more candidates among the plurality of transmission time intervals that can be configured in 14 symbols, and the user equipment A step of generating a bitmap showing the candidate for blind decoding of the physical channel, and
A process in which the transmission unit transmits the bitmap to the user device,
The transmission method. A one or more transmission time intervals is the symbol for the physical channel, among the plurality of transmission time intervals that can be configured in a 14 symbols, a process of receiving a bitmap indicating one or more candidate ,
In the candidate, the process of blindly decoding the physical channel based on the bitmap, and
An integrated circuit that controls. A one or more transmission time intervals is the symbol for the physical channel, 14 among the plurality of possible configurations of the transmission time interval in a symbol, a one or more candidate user equipment the physical A process of generating a bitmap showing the candidate for blind decoding of the channel, and
The process of transmitting the bitmap to the user device and
An integrated circuit that controls.

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