METHOD FOR IMPLEMENTING A BASE STATION

专利摘要:
range extension method in wireless communication systems. the present invention provides a method for extending the range in wireless communication systems. one embodiment of the method includes determining whether a mobile unit is within a first interval corresponding to an interval of timing advances supported by a timing advance command. this mode also includes transmitting a plurality of timing advance commands to the mobile unit, when the mobile unit is outside the first interval so that the mobile unit can be synchronized with the base station by combining information in the plurality of commands timing advance.
公开号:BR112012011479B1
申请号:R112012011479-4
申请日:2010-10-26
公开日:2021-04-06
发明作者:Fang-Chen Cheng；Jung Ah Lee
申请人:Alcatel Lucent；
IPC主号:

专利说明:

[0001] This invention generally relates to communications systems, and, more particularly, to wireless communication systems. DESCRIPTION OF RELATED ART
[0002] Wireless communication systems typically include one or more base stations or access points to provide wireless connectivity for mobile units, in a geographic area (or cell) associated with each base station or access point. The mobile units and base stations communicate through the transmission of modulated radio frequency signals through a wireless communication link, or overhead interface. The air interface includes downlink channels (or direct link) for transmitting information from the base station to the mobile unit and uplink channels (or reverse link) for transmitting information from the mobile unit to the base station . Uplink and downlink channels are typically divided into data channels, random access channels, broadcast channels, paging channels, control channels, and the like.
[0003] Mobile units can initiate communication with the base station by transmitting a message on one or more of the random access channels (RACHs). Random uplink access channels are unsynchronized and therefore can be transmitted at any time in relation to the downlink synchronization synchronized by any mobile unit within the coverage area of the base station. The receiver at the base station must therefore continuously monitor the random access channels and search for signals received on the random access channels for the predetermined sequences of symbols (sometimes referred to as the RACH preamble) on random access channels transmitted by units furniture. To make the research process feasible, the format of the random access channels must be standardized. For example, conventional random access channels in the Universal Mobile Telecommunication Services (UMTS) Long Term Evolution (LTE) system are transmitted in a subframe during a transmission time interval (TTI) of 1.08 MHz wide lms bandwidth.
[0004] The reception times for random uplink access of signals transmitted by mobile units near the center of the cell and the mobile units near the edge of the cell can be shifted by as much as the round trip delay corresponding to the cell radius. The displacement arises because the non-synchronized uplink random access signals for a particular subframe are transmitted in relation to the arrival times of the corresponding synchronized downlink subframe. A mobile unit in the center of the cell receives the synchronized downlink subframe earlier than the mobile unit at the edge of the cell (for approximately the forward delay corresponding to the cell radius) and the uplink signals transmitted from mobile units Centrals arrive at the base station earlier than uplink signals transmitted from mobile edge units (for approximately the forward delay corresponding to the cell radius). Inter-symbol interference between the random access channels associated with different subframes occurs if the random access signals associated with a subframe overlap with a subsequent subframe and therefore interfere with the random access signals associated with the subsequent subframe. Inter-symbol interference can be reduced by including a guard time in each random access channel subframe during which no uplink signal is transmitted to reduce or avoid inter-symbol interference. For example, the random access channel subframe can be divided into a 0.8ms preamble and a 102.6μs cyclic prefix that includes a copy of a portion of the sequence of symbols in the preamble. The remaining 97.4μs in the transmission time interval are reserved as a guard time.
[0005] The coverage area of a base station is related to the duration of the cyclic prefix and the guard time. For example, the conventional guard time of approximately 0.1 lms corresponds to a round trip delay for a signal that travels about 15 kilometers. Thus, a random access channel format that includes about 0.1 IR for guard time is appropriate to reduce or prevent inter-symbol interference for coverage areas or cell sizes having a radius of up to about 15 km. Likewise, the duration of the cyclic prefix is related to the size of the coverage area. For example, a cyclic prefix of about 0.1 lms is suitable for coverage areas having radii of up to about 15km. Although a range of 15 km can be considered sufficient for conventional wireless communication systems, the base station range of proposed wireless communication systems, such as LTE UMTS, is expected to increase by at least 100 km in scenarios with good conditions radio propagation, such as coverage in coastal areas.
[0006] Proposals to extend the range of the random access channel supported by base stations include increasing the transmission time interval to 2ms. For example, a proposal includes changing the structure of random access channels. In this proposal, the extended transmission time interval includes a 0.8ms RACH preamble. The length of the cyclic prefix (CP) also increases in proportion to the desired coverage area. For example, each 0, lms of additional cyclic prefix length will be responsible for the additional coverage of 15km. The holding time also increases in proportion to the length of the cyclic prefix. Thus, with the RACH preamble 0.8ms, the time available for the storage time and cyclic prefix is 2ms -0.8ms = 1.2ms. This RACH range extension proposal attempts to reduce the complexity of the RACH preamble detection receiver. However, the retention time and the cyclic prefix are considered pure overhead, because no new information can be transmitted during these intervals. Increasing the guard time or the length of the cyclic prefix far beyond the current value of 0. lms is therefore not considered a desirable way to extend the range of cells because of the high cost of resources.
[0007] In other proposals, two partitions between cyclic prefix and guard time (or guard period) can be imagined: In one case, the 1.2ms portion of the subframe that is not assigned to the preamble could be uniformly assigned to the cyclic prefix and time guard so that the RACH coverage is extended to 90km. Alternatively, the 1.2ms portion of the subframe that is not assigned to the preamble could be unevenly distributed between the length of the cyclic prefix and the guard time. The unequal distribution of the time allocated for the cyclic prefix and the guard time could extend the coverage to 100km if the length of the cyclic prefix is equal to or greater than 0.677ms. However, inter-symbol interference can occur when assignments of cyclic prefix and retention time are uneven in cases where the preamble is transmitted by a mobile unit near the edge of the cell. In addition, the signal strength received from mobile units at the edge of an extended cell, for example, mobile units that are as much as 90 or 100km from the base station, can be very low, which can reduce the likelihood of detect the preamble of the random access channel. SUMMARY OF MODALITIES OF THE INVENTION
[0008] The material revealed is aimed at addressing the effects of one or more of the problems mentioned above. The following provides a simplified summary of the revealed matter in order to provide a basic understanding of some aspects of the revealed matter. This summary is not an exhaustive overview of the material revealed. It is not intended to identify essential or critical elements of the revealed matter or to outline the scope of the revealed matter. Its sole purpose is to present some concepts in a simplified way as a prelude to the more detailed description that will be discussed later.
[0009] In one embodiment, a method for extending the range in wireless communication systems is provided. One embodiment of the method includes determining whether a mobile unit is within a first interval corresponding to an interval of timing advances supported by a timing advance command. This mode also includes transmitting a plurality of timing advance commands to the mobile unit, when the mobile unit is outside the first interval so that the mobile unit can be synchronized with the base station by combining information in the plurality of control commands. timing advance.
[0010] In another embodiment, a method for range-extending wireless communication systems is provided. This method modality includes receiving, on a mobile unit and a base station, a plurality of timing advance commands, when the mobile unit is outside a first interval corresponding to a timing advance interval supported by an advance command. timing. This mode also includes the synchronization of the mobile unit to the base station by combining information in the plurality of timing advance commands. BRIEF DESCRIPTION OF THE DRAWINGS
[0011] The material disclosed can be understood by reference to the following description taken in conjunction with the accompanying drawings, in which similar reference numbers identify similar elements, and in which: Figure 1 illustrates conceptually an exemplary mode of a wireless communication system; Figure 2 shows an exemplary embodiment of a random access channel; Figure 3 conceptually illustrates an exemplary transmitter modality that can be used to transmit RACH preambles, such as the random access channel shown in Figure 2; Figure 4 illustrates conceptually an embodiment of a receiver that can be used to detect a RACH preamble over a range associated with the structure of the RACH preamble; Figure 5 illustrates conceptually an exemplary mode of the base station that can determine whether a mobile unit is within a range supported by a timing advance command and / or a RACH preamble structure used by the mobile unit; Figure 6A conceptually illustrates an exemplary mode of a timing advance command that can be used to indicate the timing advance values; Figure 6B conceptually illustrates two timing advance commands that can be combined to signal a timing advance that is greater than the maximum timing advance value that can be signaled using the bits in a single timing advance command; Figure 7 illustrates conceptually an exemplary modality of a method or transmission of timing advance commands to the mobile units; and Figure 8 illustrates conceptually an exemplary method of receiving timing advance commands on a mobile unit.
[0012] While the revealed material is susceptible to several modifications and alternative forms, specific modalities of it were shown as an example in the drawings and will be described in detail here. It should be understood, however, that the description of modalities specific here is not intended to limit the matter disclosed to the particular forms disclosed, but, on the contrary, the intention is to cover all modifications, equivalents, and alternatives that fall within the scope of the appended claims. DETAILED DESCRIPTION OF SPECIFIC MODALITIES
[0013] Illustrative modalities are described below. In the interests of clarity, not all features of a current implementation are described in this specification. It will, of course, be appreciated that, in the development of any such real modality, numerous specific implementation decisions must be made to achieve the goals of specific developers, such as compliance with system-related and business-related constraints, which will vary from one application to another. In addition, it will be appreciated that such a development effort can be complex and time-consuming, but nonetheless, it will be a routine task for ordinary experts in the art having the benefit of this disclosure.
[0014] The material revealed will now be described with reference to the accompanying drawings. Various structures, systems and devices are represented schematically in the drawings, for the purpose of explanation only and so as not to obscure the present invention with details that are well known to those skilled in the art. However, the accompanying drawings are included to describe and explain illustrative examples of the material disclosed. The words and expressions used here must be understood and interpreted to have a meaning consistent with the understanding of those words and expressions by those skilled in the relevant art. No special definition of a term or phrase, that is, a definition that is different from the usual and common sense as understood by those skilled in the art, is intended to be implied by the consistent use of the term or phrase. Insofar as a term or phrase is intended to have a special meaning, that is, a meaning different from that understood by experts in the art, such a special definition will be expressly defined in the specification of a form of definition that directly and unequivocally provides special definition for the term or phrase.
[0015] Generally, the present application describes techniques that can be used to extend the range of base stations within a wireless communication system. As discussed here, the base station interval is related to the structure of random access preambles that the mobile units transmit to signal their presence to the base station. For example, each 0, lms of additional cyclic prefix length (and corresponding guard time interval) in the preamble can add an additional 15km coverage. However, the retention time and the cyclic prefix are considered pure overhead, because no new information can be transmitted during these intervals. Increasing the guard time or the length of the cyclic prefix far beyond the current value of 0. lms is therefore not considered a desirable way to extend the range of cells because of the high cost of resources.
[0016] Other techniques can also be used to support gap extension. For example, physical layer procedures and Long Term Evolution (LTE) physical layer parameters can be designed based on the 100 km target cell radius. Cell range extension beyond 100km can be implemented in base stations and / or eNBs: In one mode, random access preamble (RA) detection can be used: The CP preamble length RA is designed to support up to 100 km and to allow efficient implementation of correlation in the frequency domain. To support range extension, the time domain correlator can be used or, alternatively, the frequency domain correlator can be used, with compensation in the detection performance. For PUSCH transmission, limitations in the timing advance command (TA) interval can cause uplink signals received from remote users to lose time alignment and spread to adjacent subframes, causing interference. For RA 3 messages, the RA 3 message reception delay is configurable within a certain window size. The RA 3 message for users at different intervals can be programmed in different subframes (TDM). Alternatively, FDM can be used. TDM / FDM separation can also be feasible for traffic channels. Over time, the uplink timing offset can be corrected by sending relative TA commands, for example, when the base station determines that the synchronized uplink transmissions are not properly aligned with the base station timing reference. In one embodiment, the eNB receiver can support special manipulation of the signals from remote users to determine their location relative to the eNB. For example, eNB can place different Fast Fourier Transform (FFT) windows on the received random access signals, depending on the number of users (for example, 0-100km, 100-200km). The fundamental problem with the above solution is the expected loss of capacity. Remote user signals may overflow in 2 subframes provided by the programmer, at least in part because a single timing advance command does not have enough range to indicate the timing delay required for remote users. It would be desirable to be able to align the received signals over a longer interval, to avoid loss of capacity.
[0017] Modalities of the techniques described in the present application, therefore, do not depend on modifying the structure of random access messages. The techniques described here can also provide a time alignment mechanism that allows the mobile unit to receive the necessary timing advance information so that the mobile unit can quickly synchronize to the base station. Some modalities can, therefore, reduce or eliminate overflow of uplink transmissions in multiple subframes. In one embodiment, base stations can determine whether a mobile unit is separated from the base station by a distance that is within a range of timing advances supported by a timing advance command. If so, the time delay required for the mobile unit can be signaled using a single time advance command. If not, the base station can transmit a plurality of timing advance commands to the mobile unit, which can combine the information in the timing advance commands to determine the timing advance used to synchronize the base station.
[0018] Figure 1 conceptually illustrates an exemplary mode of a wireless communication system 100. In the illustrated embodiment, a base station 105 provides wireless connectivity for mobile units 110 via air interfaces or wireless communication links 115. Techniques for creating, maintenance, de-assignment, and / or tear down wireless communication links 115 are known in the art and in the interest of clarity only aspects of creating, maintaining, operating, de-assigning, and / or tearing down wireless communication links 115 that are relevant to the claimed matter will be discussed here. In addition, persons of ordinary skill in the art having the benefit of the present disclosure should appreciate that the particular wireless communication systems shown in Figure 1 are intended to be illustrative and not to limit the claimed matter. For example, alternative embodiments of the wireless communication system 100 may include other numbers of base stations 105, and / or mobile units 115.
[0019] Base station 105 and mobile units 110 can initiate wireless communication over wireless communication links 115 by exchanging random access messages and timing advance commands. In the illustrated embodiment, the base station 105 and mobile units 110 are configured to communicate over time synchronized traffic and data channels. For example, frequency division duplexing (FDD) and / or time division duplexing (TDD) channels can use a frame structure for uplink and / or downlink transmissions in which each channel is divided into 5ms frames or 10ms which are each divided into subframes or intervals, for example, 0.5ms time intervals. However, base stations 105 and mobile units 110 may not initially be synchronized, at least in part because of the variable (and initially unknown) round-trip time delay between base station 105 and each mobile unit 110. signal processing within the base stations 105 and / or the mobile units 110 can also contribute to the lack of synchronization. As discussed herein, the structure of a random access channel transmitted from a mobile unit 110 to the base station 105 corresponds to the slot (R) of the base station 105.
[0020] Figure 2 shows an exemplary embodiment of a random access channel 200. In this embodiment, the random access channel 200 includes a cyclic prefix 205 and a transmission sequence 210, which may include the preamble of the random access channel (RACH). For example, a physical layer random access preamble (such as random access channel 200) may consist of a cyclic prefix 205 of length TCP and a portion of sequence 210 of length TSEq- Examples of parameter values are listed in Table 1 and depend on the frame structure and the random access configuration. Higher layers in the protocol stack can control the preamble format. The preamble formats listed in Table 1 are defined according to the standards and / or protocols established by the Third Generation Partnership Project (3GPP) and, in particular, in 3GPP TS 36,211 v9.1.0, entitled 3GPP Technical Specification for Group Radio Access, Evolved Universal Terrestrial Radio Access (E-UTRA), Physical Channels and Modulation. The basic time unit (Ts) can also be defined according to 3GPP standards and / or protocols. Table 1: Preamble parameters of random access.
[0021] Formats 1 and 3 in Table 1 can be used to reach a range of about 100km because these formats use relatively longer cyclic prefixes. As used herein, the term "approximately" is used to indicate that, under perfect conditions, the round trip delay corresponding to the duration of the cyclic prefix for these formats corresponds to an interval of 100km. However, environmental conditions and other factors can cause the effective range achieved in practice, to vary from this ideal value although people with current knowledge in the art would still refer to the range as being "100 km" or "approximately 100 km."
[0022] In a modality that can be adopted in 3GPP standards and / or protocols, the supported TA command range can be limited to [0, ..., 1282], for example, in TS 36,213 and corresponding RAN2 specification TS 36,321. The TA command interval can be extended to [0, ..., 2047] without changing the MAC PDU structure using modalities of the techniques described here. For example, in the case of a random access response (RA) with an 11-bit timing advance command, TA indicates the NTA values by index values of TA = 0, 1, 2,. . .1282, where an amount of time alignment is given by NTA = TA x 16 and NTA is defined in the relevant 3GPP specifications. The Timing Advance Command field indicates the index value TA (0, 1, 2 ... 1282) that can be used to control the amount of timing adjustment applied by a mobile unit. In one embodiment, the length of the Timing Advance Command field is 11 bits. Note that 20512 = 16 * 12 82, as the applicable timing advance can be defined as 16 Ts steps. The base station and the mobile unit can be synchronized with the timing advance so that the transmission of the number of uplink radio structures would start from the mobile unit can begin (NTA + NTA offset) x Ts seconds before the start of the frame corresponding downlink radio frequency in the mobile unit, where 0 ≤ NTA ≤ 2 0512, NTAoffset = 0 for frame type 1 and NTA offset = 624 for frame type 2. Note that not all intervals radio structure can be transmitted. An example of this is TDD, where only a subset of the intervals in a radio frame is transmitted.
[0023] Figure 3 conceptually illustrates an exemplary embodiment of a transmitter 300 that can be used to transmit RACH preambles, such as the random access channel 200 shown in Figure 2. In the illustrated embodiment, transmitter 300 is configured for unsynchronized RACH transmission. For example, a CAZAC sequence of length L can be used as the RACH overflow 305. The sequence is converted into a frequency domain by discrete Fourier transform (DFT) precoding in a 310 series / parallel converter and a DFT 315 unit. A mapper 320 can then be used to map precoding signals to appropriate RACH subcarriers. The sequence can then be converted to time domain samples by a fast reverse Fourier transform (IFFT) element 325 and then converted (with a parallel converter / 330 series) back to a serial signal stream. In the time domain, zero samples are added in the space periods before transmission using a 335 space inserter.
[0024] Referring again to Figure 1, base station 105 can use the received random access message to estimate the distance between base station 105 and mobile unit 110 that transmitted the random access message. In one embodiment, the base station 105 can correlate the received random access message with a reference signal. By performing this correlation over a timing window corresponding to the base station interval (R), the base station 105 can estimate the relative delay between the timing reference at the base station 105 and the time of receiving the random access message.
[0025] Figure 4 illustrates conceptually an embodiment of a receiver 400 that can be used to detect a RACH preamble over a range associated with the structure of the RACH preamble. In the illustrated embodiment, the receiver 400 is configured to detect unsynchronized RACH preambles and Figure 4 shows an implementation in the frequency domain of a correlation detector 400. In the illustrated embodiment, a received signal is pre-processed by an addition operation. overlap 405. The signal is then converted into the frequency domain by a fast Fourier Transform (FFT) element in the frequency domain correlator 410. After multiplication by the reference RACH sequence 415, the signal is converted back to time domain using a discrete inverse Fourier transform (IDFT). The energy of the time domain signal can then be determined within a limited search window (at 420) and compared with a threshold in the energy detector 425. If a RACH preamble is detected within the received signal, the receiver output 400 indicates an estimate of the round-trip delay of the detected RACH sequence.
[0026] Instead of using a single reference sequence 415, alternative modalities of frequency domain correlator 410 in alternative modalities of receiver 400 can implement a set of parallel RACH preamble detection processes that each detect a disjunction interval of RACH transmission locations possible. For example, each of the parallel RACH preamble detection processes can compare the received signal to a plurality of 1-N reference signals. Each of the 1-N reference signals can be used to detect user RACH preambles at different distance intervals. For example, a reference signal (and associated parallel detection process) can be used to detect users in the 0-15km range, another reference signal (and associated parallel detection process) can be used to detect users in the range 15-30km, and another reference signal (and associated parallel detection process) can be used to detect users in the 30-45km range.
[0027] Referring again to Figure 1, since the base station 105 has estimated the distance to the mobile unit 115 that the random access message was transmitted, the base station 105 can determine a timing advance that can be used to synchronize the transmissions. between base station 105 and mobile unit 115. For example, if mobile unit 115 (1) transmits a random access message to base station 105, base station 105 can determine the round trip delay for the mobile unit 115 (1) and then define a suitable timing advance that can be used by the mobile unit 115 (1) to adjust its timing to synchronize with the base station 105. Timing advance commands can be set to support an interval of the time advance values that correspond to the base station (R) interval 105. The range of values supported by the time advance commands can therefore also correspond to the interval (R) defined by the structure of the RACH preamble. For example, a timing advance command may include a selected number of bits that can be used to transmit different timing advance values within the supported range (R).
[0028] The range of the base station 105 can be extended using multiple timing advance commands to transmit information indicating a net timing advance that is greater than the maximum timing advance that can be indicated by a single timing advance command. In the illustrated embodiment, the base station 105 can determine whether a mobile unit 115 is beyond the range (R) that is supported by the timing advance commands and / or the structure of the RACH preambles transmitted by the mobile units 115. The base station 105 can then transmit the multiple timing advance commands that indicate the largest timing advance values that are needed to synchronize the mobile units 115 that are out of range (R). For example, base station 105 may transmit two (or more, in some cases) timing advance commands to indicate a timing advance value that mobile unit 115 (2) would need to synchronize with base station 115.
[0029] Figure 5 illustrates conceptually an exemplary embodiment of the base station 500 that can determine whether a mobile unit is within a range supported by a timing advance command and / or a RACH preamble structure used by the mobile unit. In the illustrated embodiment, the base station 500 receives wireless signals over an antenna 505. A version of the received signals is transmitted to a receiver 510, such as receiver 400 shown in Figure 4. Receiver 510 is configured to search for signals received within of a timing window that corresponds to the range of the base station 500. For example, receiver 510 may look for a timing window that corresponds to round trip delays for distances in the range 0-100km. If a RACH preamble is detected within the timing window, then receiver 510 can estimate the round-trip delay of the received signal and transmit this information to timing advance logic 515, which can generate an appropriate timing advance command. which indicates a time advance value that can be used to correct the round trip delay and synchronize the base station 500 with the mobile unit. The timing advance command can then be transmitted via antenna 505.
[0030] A receiver 500 can also be used to search for signals received within a timing window that corresponds to distances outside the range supported by the timing advance command and / or the RACH preamble structure used by the mobile unit. In the illustrated embodiment, the received signals are delayed by a delay element 525 for a time corresponding to the round-trip delay within the maximum interval supported by the timing advance command and / or the RACH preamble structure. For example, the delay element 525 can delay the signals received by a round trip delay corresponding to an interval of 100 km. The receiver 520 can then search for the delayed signal within a timing window that corresponds to the interval supported by the timing advance command and / or the RACH preamble structure. For example, if the received signal is delayed before reaching receiver 520, receiver 520 may look for a timing window that corresponds to the round trip delay for distances in the range of 100-200km. If a RACH preamble is detected within the timing window, then receiver 520 can estimate the round-trip delay of the received signal and transmit this information to timing forward logic 515, which can generate an appropriate set of forward commands timeout which, in combination, indicates a timeout advance value that can be used to correct the round trip delay and synchronize the base station 500 with the mobile unit. The timing advance commands can then be transmitted via antenna 505.
[0031] In the illustrated embodiment, receivers 510, 520 are described as functional entities within base station 500. Receivers 510, 520 can therefore concurrently process the received signal and the delayed version of the received signal to search for RACH preambles within the timing windows many different. However, in alternative embodiments, receivers 510, 520 can be representative of a single physical receiver that is configured to perform searches for both the received signal and the delayed version of the received signal. In that case, the physical receiver implementing the receivers 510, 520 can search for the received signals in the first window during a first time slot and in a second window during a second time slot.
[0032] Figure 6A conceptually illustrates an exemplary mode of a timing advance command 600 that can be used to indicate the timing advance values. In the illustrated embodiment, the time advance command 600 includes a plurality of bits 655 that can be used to transmit a time advance value. The number of bits 6 05 can be predetermined and can be selected to allow the timing advance command 600 to transmit the timing advance values within a range such as a range corresponding to the range of a base station and / or the range supported by a RACH preamble structure. The timing advance command 600 may also include one or more reserved bits 610. In the illustrated embodiment, reserved bit 610 is set to a value of "0".
[0033] Figure 6B conceptually illustrates two timing advance commands 615, 620 that can be combined to signal a timing advance that is greater than the maximum value of the timing advance that can be signaled using the bits in a single timing advance command. timing. For example, each timing advance command 615, 62 0 may have a bit width that supports a range of allowable index values TA (0, 1, 2 ... 1282) that are used to indicate timing advances within the interval corresponding to the interval of a base station and / or the interval supported by a RACH preamble structure. To signal increased timing advances, the first timing advance command 615 can transmit an index value outside the allowable range, for example, by setting one or more of the reserved bits 610 to a value of "1" to indicate a value of 1283 for the index. When the mobile unit receives the first timing advance command 615, it recognizes that a second timing advance command 620 is going to be transmitted, because the index value is outside the allowed range.
[0034] The index value on the second time advance command 620 can be selected so that the sum of the maximum value (for example, 1282) and the value indicated on the second time advance command is equal to the extended time advance value. which is used by mobile units within the extended range to synchronize to the base station. Although two timing advance commands 615, 620 are shown in Figure 6, alternative modalities may use more timing advance commands to signal higher timing advance values. For example, the second timing advance command 620 may transmit an index value outside the allowable range, for example, by setting one or more of the reserved bits 610 to a value of "1" to indicate a value of 1283 for the index. The mobile unit can then know that at least one additional time advance command is to be transmitted and that it must combine the information in all time advance commands to determine the time advance value that should be used in the extended interval. . Modalities of this technique can allow the range of a base station to be extended as necessary to higher values per chain and any number of timing advance commands, which can potentially "test future" of this approach. Modalities of such a base station may also be able to determine mobile unit distances within additional intervals, such as 0-100km, 100-200km, 200-300km, etc.
[0035] Figure 7 illustrates conceptually an exemplary embodiment of a method 700 for transmitting timing advance commands to the mobile units. In the illustrated embodiment, a base station receives a random access message from a mobile unit and uses this message to estimate or determine (at 705) a distance or separation (R) between the mobile unit and the base station. For example, during an initial access procedure, the mobile unit can transmit the random access preamble in a predetermined subframe and the base station can use the random access preamble to determine (in 700) the distance (R). The base station can then determine (at 710) whether the mobile unit is within a distance (R1) that corresponds to a distance that is supported by the preamble structure and / or a distance that corresponds to the range of timing advances supported by a timing advance command. If the mobile unit is within the distance (R1), then the base station can determine a suitable timing advance for the synchronization of the mobile unit and transmit a timing advance command indicating this timing advance to the mobile unit. In one embodiment, the base station can also simultaneously transmit a reference timing signal so that the mobile unit can use the timing advance to synchronize the uplink transmissions to the reference timing signal.
[0036] Multiple timing advance commands can be transmitted when the base station determines (in 710) that the mobile unit is beyond or outside the distance (R1). In the illustrated embodiment, the base station determines the timing advance required to synchronize the mobile unit to the base station and transmits (in 720) a timing advance command indicating a portion of the required timing advance and also indicating that a forward command Subsequent time delay must be transmitted. For example, the time advance command may include a value of 1283 which indicates a time advance of the maximum value supported by the time advance command (1282). The value of 1283 in the time advance command also indicates that another time advance command must be transmitted, because the value of 1283 is outside the range (0-1282) supported by the time advance command. One or more subsequent timing advance commands can then be transmitted (at 725) to indicate the additional timing advance. For example, to indicate a total timing advance of 2000, an initial RA response is sent (at 720) with the value of 12 83 and then another RA response is sent (at 72 5) in a later subframe with a value 718 timing advance,
[0037] Figure 8 conceptually illustrates an exemplary embodiment of a method 800 for receiving timing advance commands on a mobile unit. In the illustrated embodiment, the mobile unit transmitted a random access message through the air interface to the base station. For example, during the initial access procedure, the mobile unit can transmit a random access preamble in a predetermined subframe. The mobile unit can then wait for a response from the base station. For example, the mobile unit can monitor a common search space (for example, a physical downlink control channel, PDCCH) for a random access response identified by the RA-RNTI within a preconfigured window. The RA response window starts in three subframes after the preamble transmission has ended. The window length is configured by an upper layer parameter, for example, using the Response Window Size in the Common Configuration - RACH (IE) information element in the radio resource control (RRC message).
[0038] In the illustrated mode, the mobile unit receives (in 805) a response including a base station advance command. The mobile unit then determines (at 810) whether the timing advance command is within the range supported by a single timing advance command. If so, the mobile unit can process the timing advance command and advance (at 815) its timing to synchronize with the base station. For example, if the random access response contains a random access preamble identifier corresponding to the transmitted Random Access preamble, the mobile unit can: consider this random access response reception to be successful, process the received Timing Advance Command, and perform (in 815) a timing alignment procedure, for example as described in Section 5.2 of TS 36,321. In one embodiment, the mobile unit may have a configurable "timeAlignmentTimer" timer that is used to control how long the mobile unit is considered to be the aligned uplink time. In one embodiment, the mobile unit can also apply the timing advance command, when a MAC timing element of the timing advance command is received in the Random Access Response message. The mobile can also start or restart timeAlignmentTimer. When the Random Access Preamble has not been selected in the MAC layer on the handset, the handset can apply the Timing Advance Command and start or restart timeAlignmentTimer. Otherwise, if the timeAlignmentTimer is not working, the mobile unit can: apply the Timing Advance Command and start timeAlignmentTimer. When the containment resolution is considered unsuccessful, the mobile unit can stop timeAlignmentTimer. Otherwise, the mobile unit may ignore the received Timing Advance Command. When timeAlignmentTimer expires, the mobile unit can release all HARQ buffers, notify RRC to release physical uplink control channel resources (PUCCH / SRS), and eliminate any configured downlink assignments and uplink guarantees.
[0039] The mobile unit can wait and receive (at 720) an additional timing advance command, when the mobile unit determines (at 810) that the timing advance command is outside the range supported by a single timing advance command. The mobile unit can then combine (in 725) the timing advance as indicated in the initial and additional timing advance commands as discussed here. Timing of the mobile unit can be advanced (at 730) using the combined timing advance as indicated in the multiple timing advance commands. In one embodiment, once the timing advance command is received in an RA response message, the mobile unit is configured to allow reception of TA commands in multiple subframes. For example, if the Timing Advance Command received is within the allowable index value TA (0, 1, 2 ... 1282), the mobile unit can apply (in 715) the Timing Advance step. Otherwise, if the Timing Advance Command received is outside the permitted TA value index (0, 1, 2 ... 1282), the mobile unit can apply the Timing Advance Command assuming the TA index value of 1282 and wait for a Random Access Response message within the allowed TA value index (0, 1, 2 ... 1282) until the received Timing Advance Command falls within the allowed TA value index (0, 1, 2 ... 1282). For example, if the base station determines a required Timing Advance index value 2000, the mobile unit can receive (at 705), an initial RA response with a Timing Advance value of 1283. Another RA Response can then be received ( in 720) in a subsequent subframe with a Timing Advance value of 718. The mobile unit can then apply (in 730) the combined Timing Advance value of 2000 for RA 3 message transmission.
[0040] In summary, the present application describes modalities for an alternative approach to cell range extension. The proposed techniques are based on the ability of the base station and / or eNB to estimate round-trip delay corresponding to a large cell radius and to generate Timing Advance Commands that are transmitted in various RA response messages. Modalities of the techniques described here provide a modular way to support extended cell range beyond the Timing Advance Command range, which is currently limited to 100km.
[0041] Parts of the revealed matter and corresponding detailed description are presented in terms of software, or algorithms and symbolic representations of operations on bits of data within a computer memory. These descriptions and representations are those by which those of ordinary skill in the art effectively carry the substance of their work to others of ordinary skill in the art. An algorithm, as the term is used here, and as it is used in general, is designed to be a self-consistent sequence of steps that lead to a desired result. The steps are those that require physical manipulation of physical quantities. Generally, although not necessarily, these quantities take the form of optical, electrical, magnetic or capable of being stored, transferred, combined, compared, and otherwise manipulated. It has sometimes proved convenient, mainly for reasons of common use, to refer to these signs as bits, values, elements, symbols, characters, terms, numbers or the like.
[0042] It should be borne in mind, however, that all of these similar terms are to be associated with the appropriate physical quantities and are merely convenient labels applied to these quantities. Unless specifically stated otherwise, or as is apparent from the discussion, terms such as "process" or "computation" or "calculate" or "determine" or "show" or the like, refer to the action and processes of a computer system, or similar electronic computing device, that manipulates and transforms the data represented as electronic, physical quantities within the computer's system records and memories into other data equally represented as physical quantities within the system's computer memories or records or any other transportation, information storage or display devices.
[0043] Also note that the software aspects implemented from the disclosed subject are usually encoded in some form of storage medium or program implemented over some type of transmission medium. The program storage medium can be magnetic (for example, a floppy disk or hard disk drive) or optical (for example, a read-only compact disk memory, or "CD-ROM"), and it can be just reading or random access. Likewise, the transmission medium can be twisted wire pairs, coaxial cables, optical fiber, or some other suitable transmission medium known in the art. The subject described is not limited by these aspects of any given implementation.
[0044] The particular modalities disclosed above are only illustrative, as the material disclosed can be modified and practiced in different but equivalent ways for those skilled in the art having the benefit of the teachings given here. In addition, no limitation is intended for the details of construction or design shown here, except as described in the claims below. Therefore, it is evident that the particular modalities disclosed above can be altered or modified and all such variations are considered within the scope of the disclosed subject. Therefore, the protection sought here is as defined in the claims below.

权利要求:
Claims (10)
[0001]
Method for implementation in a base station, characterized by the fact that it comprises: determining whether a mobile unit is within a first interval corresponding to a range of timing advances supported by a timing advance command; and transmitting a plurality of timing advance commands to the mobile unit, when the mobile unit is outside the first interval so that the mobile unit can be synchronized with the base station using a sum of a plurality of time advances in the plurality of timing advance commands.
[0002]
Method according to claim 1, characterized by the fact that determining whether the mobile unit is within the first interval comprises searching for received signals on a random access channel in at least one first timing window corresponding to the first interval and searching for received signals in the random access channel in at least a second timing window corresponding to at least a second interval that is beyond the first interval.
[0003]
Method, according to claim 2, characterized by the fact that determining whether the mobile unit is within the first range comprises searching for signals received on a random access channel in at least one first timing window corresponding to a first interval of 100km and searching the signals received on the random access channel in at least a second timing window corresponding to at least a second interval of 100km to 200km.
[0004]
Method according to claim 1, characterized in that determining whether the mobile unit is within the first range comprises determining whether the mobile unit is within a range of timing advances that can be signaled using a timing advance message having a predetermined number of bits.
[0005]
Method according to claim 1, characterized by the fact that transmitting the plurality of timing advance commands comprises the transmission of a first timing advance command including a first value of a timing advance that is outside the range supported by the command time-advance command to indicate that at least a second time-advance command is to be transmitted, and where transmitting the plurality of time-advance commands comprises transmitting said at least a second time-advance command including at least a second value of the timing advance such that the first value and said at least a second value can be added to form a sum indicating a timing advance that corresponds to a distance outside the first range.
[0006]
Method according to claim 1, characterized in that it comprises the transmission of a reference timing signal concurrently with the plurality of timing advance commands so that the mobile unit can synchronize with the reference timing signal using the plurality of timing advance commands.
[0007]
Method for implementation in a mobile unit, characterized by the fact that it comprises: receiving, from a base station, a plurality of timing advance commands when the mobile unit is outside a first interval corresponding to a timing advance interval supported by a timing advance command; synchronize the mobile unit to the base station using a sum of a plurality of timing advances in the plurality of timing advance commands.
[0008]
Method according to claim 7, characterized in that it receives the plurality of timing advance commands comprises receiving the plurality of timing advance commands when the base station determines that the mobile unit is outside a first range of 100km.
[0009]
Method according to claim 7, characterized in that it receives the plurality of timing advance commands comprises receiving a first timing advance command including a first value of a timing advance that is outside the range supported by the advance command to indicate that at least a second timing advance command is to be transmitted, and in which receiving the plurality of timing advance commands comprises transmitting said at least a second timing advance command including at least a second value of the timing advance such that the first value and said at least a second value can be added to form a sum indicating a timing advance that corresponds to a distance outside the first range.
[0010]
Method according to claim 7, characterized in that it comprises receiving a reference timing signal concurrently with receiving the plurality of timing advance and synchronization commands for the reference timing signal using the plurality of commands timing advance.

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EP2494826A1|2012-09-05|

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JP2013509815A|2013-03-14|

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WO2011059689A1|2011-05-19|

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2020-12-08| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2021-02-23| B09W| Decision of grant: rectification|Free format text: RETIFICA-SE O PARECER DE DEFERIMENTO NOTIFICADO NA RPI 2605 DE 08/12/2020. |

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2021-04-06| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 10 (DEZ) ANOS CONTADOS A PARTIR DE 06/04/2021, OBSERVADAS AS CONDICOES LEGAIS. |

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