Source: https://patents.google.com/patent/JP2011512705A/en
Timestamp: 2019-12-07 15:39:03
Document Index: 552514756

Matched Legal Cases: ['Application No. 61', 'Application No. 61', 'arts 1000', 'art 1000', 'art 1010', 'art 800', 'art 800']

JP2011512705A - Sounding reference signal configuration - Google Patents
Sounding reference signal configuration Download PDF
JP2011512705A
JP2011512705A JP2010541778A JP2010541778A JP2011512705A JP 2011512705 A JP2011512705 A JP 2011512705A JP 2010541778 A JP2010541778 A JP 2010541778A JP 2010541778 A JP2010541778 A JP 2010541778A JP 2011512705 A JP2011512705 A JP 2011512705A
JP2010541778A
2008-01-08 Priority to US636408P priority Critical
2008-02-05 Priority to US690108P priority
2009-01-08 Application filed by ノキア シーメンス ネットワークス オサケユキチュア filed Critical ノキア シーメンス ネットワークス オサケユキチュア
2009-01-08 Priority to PCT/EP2009/050148 priority patent/WO2009087182A2/en
2011-04-21 Publication of JP2011512705A publication Critical patent/JP2011512705A/en
A method, apparatus, and computer program implemented on a computer-readable medium for generating an uplink message to be transmitted to a base station.
The generated uplink message includes a sounding reference signal based on the accessed data. In response to the transmission of the uplink message, an uplink scheduling grant signal is received from the base station via the downlink. In response to the received uplink scheduling grant signal, an uplink data transmission is transmitted to the base station.
The present invention relates to uplink (UL) transmission of Universal Mobile Telecommunication System (UMTS) Terrestrial Radio Access Network (UTRAN) Long Term Evolution (LTE). More particularly, the present invention relates to sounding reference signal (SRS) transmission and configuration.
This application is a priority of US Provisional Patent Application No. 61 / 006,634, filed Jan. 8, 2008, and US Provisional Patent Application No. 61 / 006,901, filed Feb. 5, 2008. Insist on the right. The disclosures of these applications are incorporated herein by reference in their entirety.
Wireless communication networks are well known and constantly evolving. For example, Universal Mobile Telecommunications System (UMTS) is one of the third generation (3G) cellular telephone technologies. Currently, the most common form of UMTS uses wideband code division multiple access (W-CDMA) as the basic air interface standardized by the Third Generation Partnership Project (3GPP).
Currently, worldwide UMTS networks are being upgraded to increase the data rate and capacity of downlink packet data. In order to ensure further competitiveness of UMTS, various concepts of UMTS Long Term Evolution (LTE) are being investigated to achieve high data rates, low latency and packet optimized radio access technologies.
3GPP LTE (Long Term Evolution) is the name given to a project within the third generation partnership project to improve the UMTS mobile phone standard and address future demands. The goals of this project include improving efficiency, reducing costs, improving services, taking advantage of new spectrum opportunities, and integrating well with other open standards. The LTE project gives rise to an evolved new release 8 of the UMTS standard that includes most or complete extensions and changes to the UMTS system, rather than a single standard.
The characteristics of the so-called “4G” networks, including the evolved UMTS, are based on the transmission control protocol / Internet protocol (TCP / IP), which is basically the core protocol of the Internet, and for voice, video and messaging. It is a built-in high-level service.
The sounding reference signal (SRS) is generally transmitted over a wide bandwidth to the Node B (ie base station) in order to find the best resource unit (RU) to transmit from the user equipment (UE). . However, because the maximum UE transmit power is limited, the channel quality indication (CQI) measurement accuracy is reduced when the SRS signal is degraded, for example, when a UE located near the edge of a cell transmits an SRS. The quality may deteriorate. This degradation of SRS can cause errors in optimal RU assignment and in the selection of modulation and code schemes (MCS). Therefore, improving the transmission of SRS from the UE helps to achieve maximum user throughput. Thus, the SRS can be designed to allow channel-aware scheduling and fast link adaptation for PUSCH for UL data transmission. SRS is also used as a reference signal (RS) for closed loop power control (PC) for both physical uplink shared channel (PUSCH) and physical uplink control channel (PUCCH).
In current LTE, SRS aspects can be configured semi-statically by the UE, eg, as part of radio resource control (RRC) signaling. In particular, the UE can specify various attributes as part of the uplink communication to the Node B. For example, a change in SRS can be used to change the bandwidth (BW) used by the UE, eg, requesting a narrowband or broadband SRS BW for a given operating bandwidth. it can. When adjusting the bandwidth, SRS transmissions should ideally not puncture the PUCCH region, which may also occur with persistent PUSCH.
The UE can also adjust the duration of SRS. For example, an SRS may be defined as a “one-shot” transmission or may be defined as an indefinite transmission that is disabled or valid until the end of the session. The UE can also adjust the SRS period. For example, the period may be 2, 5, 10, 20, 40, 80, 160, or Xms. The UE may also adjust the SRS to include a 3-bit cyclic shift, as described in detail below.
Also, it is determined that the cyclic shift of the SRS sequence is indicated by 3 bits. Three bits can be used to indicate 2 3 or 8 different cyclic shift values. However, the problem that arises is how to maximize the cyclic shift separation between SRS resources.
Another problem that arises due to the above-described UE-based customization of SRS is to support code tree-based bandwidth specification with maximum cyclic shift separation.
In order to provide efficient specification of SRS with different transmission bandwidths, one conventional scheme provides bandwidth specification based on orthogonal variable spreading factor (OVSF) code specification in a tree structure. Although described herein with reference to OVSF, it is clear that other tree-based designations such as Walsh codes are also known and can be used in other ways.
OVSF and other tree-based codes support both hopping-based and localized-based multiplexing for SRS with a transmission bandwidth that is narrower than the system bandwidth to maximize user throughput performance in various cell deployment scenarios can do. Furthermore, the conventional scheme is adapted to achieve an efficient SRS hopping method based on switching of branches in the OVSF code tree. However, this conventional scheme does not take into account the current SRS assumptions made in 3GPP. For example, this scheme may not work properly if the SRS transmission punctures the PUCCH region or if certain BW options are allowed for the SRS.
In response to the current state of the art, several embodiments have been developed, particularly in response to technical problems and needs that have not been fully solved by currently available communication system technologies. Accordingly, several embodiments have been developed to provide a sounding reference signal construction method, apparatus, and computer program implemented on a computer readable medium.
According to one embodiment, generating an uplink message to be transmitted to the base station, wherein the generated uplink message includes a sounding reference signal based on the accessed data. A provided method is provided. The method also includes receiving an uplink scheduling grant signal from the base station via the downlink in response to the transmission of the uplink message. The method further comprises transmitting an uplink data transmission to the base station in response to the received uplink scheduling grant signal.
According to another embodiment, a method is provided comprising receiving an uplink message including a sounding resource signal allocation bandwidth from a mobile station. The method also comprises transmitting an uplink scheduling grant signal over the downlink to the mobile station. The method also includes receiving an uplink data transmission from the mobile station in response to the transmitted uplink scheduling grant signal.
According to another embodiment, an apparatus is provided comprising a transmitter configured to transmit a generated uplink message including a sounding reference signal to a base station. The apparatus also includes a receiver configured to receive an uplink scheduling grant signal from the base station via the downlink. The transmitter is further configured to transmit an uplink data transmission to the base station in response to the received uplink scheduling grant signal.
According to another embodiment, an apparatus is provided comprising a receiver configured to receive an uplink message that includes a sounding resource signal allocation bandwidth. The apparatus also includes a transmitter configured to transmit an uplink scheduling grant signal over the downlink to the mobile station. The receiver is further configured to receive an uplink data transmission from the mobile station in response to the transmitted uplink scheduling grant signal.
According to another embodiment, an apparatus is provided comprising means for transmitting a generated uplink message including a sounding reference signal to a base station. The apparatus also comprises receiver means for receiving an uplink scheduling grant signal from the base station via the downlink. Transmission means for transmission transmits an uplink data transmission to the base station in response to the received uplink scheduling grant signal.
According to another embodiment, an apparatus is provided comprising receiving means for receiving an uplink message including a sounding resource signal allocation bandwidth. The apparatus also comprises transmission means for transmitting an uplink scheduling grant signal over the downlink to the mobile station. The receiving means receives an uplink data transmission from the mobile station in response to the transmitted uplink scheduling grant signal.
According to another embodiment, a computer program implemented on a computer readable medium is provided that is configured to control a process for performing the method. The method comprises generating an uplink message to be transmitted to a base station, the uplink message including a sounding reference signal based on the accessed data. The method also includes receiving an uplink scheduling grant signal from the base station via the downlink in response to the transmission of the uplink message. The method also includes transmitting an uplink data transmission to the base station in response to the received uplink scheduling grant signal.
According to another embodiment, a computer program implemented on a computer readable medium is provided that is configured to control a process for performing the method. The method comprises receiving an uplink message including a sounding resource signal allocation bandwidth. The method also comprises transmitting an uplink scheduling grant signal over the downlink to the mobile station. The method also includes receiving an uplink data transmission from the mobile station in response to the transmitted uplink scheduling grant signal.
In order to easily understand the effects of this embodiment, the above-described embodiment will be described in detail with reference to the specific embodiment shown in the accompanying drawings. With the understanding that these drawings are only exemplary embodiments and therefore do not limit the scope of the invention, the embodiments will be described in detail using the accompanying drawings.
1 is a high level circuit diagram of a UMTS system. FIG. FIG. 3 is a high level circuit diagram of a user equipment according to one embodiment. FIG. 4 is an SRS bandwidth allocation according to one embodiment. FIG. 2 is an SRS bandwidth allocation configuration according to one embodiment. 2 is an SRS bandwidth allocation configuration according to one embodiment. It is a SRS transmission bandwidth structure table for various transmissions by channel bandwidth. FIG. 4 is an SRS bandwidth allocation according to one embodiment. FIG. 4 is a process flowchart of SRS bandwidth allocation according to one embodiment. 6 illustrates an SRS bandwidth allocation method according to an embodiment. 6 illustrates an SRS bandwidth allocation method according to an embodiment. 6 is a chart for comparing sounding errors using different minimum sounding reference signal bandwidths according to one embodiment. 6 is a chart for comparing sounding errors using different minimum sounding reference signal bandwidths according to one embodiment. Fig. 4 illustrates a method for handling dynamically changing PUCCH bandwidth according to one embodiment. 12 is an example table illustrating a method for handling the dynamically changing PUCCH bandwidth of FIG. 11 according to one embodiment.
It will be readily appreciated that the components of this embodiment that are generally described and illustrated in the drawings can be designed and arranged in a wide variety of different configurations. Accordingly, the following detailed description of embodiments of the apparatus, systems and methods illustrated in the accompanying drawings is not intended to limit the scope of the embodiments shown in the claims, but merely to represent selected embodiments. Absent.
The features, structures, and characteristics of the embodiments described throughout this specification can be combined as appropriate in one or more embodiments. For example, throughout this specification "an embodiment," "some embodiments," or similar terms are used to describe an embodiment in which a particular feature, structure, or characteristic described in connection with that embodiment is at least one. It is included in. Thus, throughout this specification, when "in one embodiment," "in some embodiments," "in other embodiments," or similar terms appear, all of them do not necessarily refer to the same group of embodiments. Rather, the features, structures, or characteristics described herein may be combined as appropriate in one or more embodiments.
Depending on the above and other needs, these embodiments provide a configuration for a sounding reference signal that supports maximum cyclic shift separation between SRS resources. In another embodiment, equations for calculating actual cyclic shift values for different SRS bandwidths are disclosed along with an efficient SRS signaling scheme. In particular, the SRS configuration in some embodiments can be constructed using three criteria where the SRS signal is based on an existing demodulated reference signal (DM RS) signal. As described in LTE Release 8, maximum cyclic shift separation is provided for 8 parallel cyclic shifts, and support for code tree based bandwidth specification is provided. Furthermore, SRS transmissions in other embodiments may prevent the PUCCH region from “puncturing” or otherwise attempt to transmit via the RB reserved for PUCCH. Similarly, in other embodiments, SRS can also be prevented from puncturing persistent PUSCH assignments.
FIG. 1 shows a UMTS system 100. In particular, the UMTS system 100 includes one or more Node Bs 110 that define one or more cells 101 and a plurality of user equipments (UEs) 120 associated with the one or more cells. The radio interface between UE 120 and Node B 110 is referred to as UU 130.
Node B 110 (also known as Enhanced Node B or eNB in LTE) is a term used in UMTS to represent BTS (Base Transceiver Station). In contrast to the Global System for Mobile Communications (GSM) base station, Node B 110 uses WCDMA as an air transport technology. Node B 110 is equipped with radio frequency transmitter (s) and receiver (s) to communicate directly with a mobile station that freely moves around, ie, UE 120. In this type of cellular network, UEs 120 do not communicate directly with each other, but communicate with Node B 110.
Traditionally, Node B 110 has minimal functionality and is controlled by an RNC (Radio Network Controller). However, this changes with the advent of High Speed Downlink Packet Access (HSDPA), where some logic (eg, retransmission) is handled at Node B 110 during a short response time.
Using WCDMA technology in LTE allows cells belonging to the same or different Node B 110 and controlled by different RNCs to overlap and use the same frequency (actually, the entire network is only one frequency pair To achieve soft handover between cells.
Since WCDMA often operates at higher frequencies than GSM, the cell range is significantly smaller than GSM cells, and unlike GSM, the cell size is not constant ("cell breathing (" a phenomenon known as cell breathing). This requires a large number of Node Bs 110 and careful planning in 3G (UMTS) networks. However, the power requirements at Node B 110 and UE 120 (user equipment) are very low.
Since LTE is augmented with a radio technology called E-UTRAN, the Node B (eg, eNB) 110 may handle radio resource management and radio access control in the cell where the device provides coverage. it can. The device may be, for example, an eNB, a base station or a radio network controller (RNC). Thus, Node B 110 can perform resource management, admission control, scheduling tasks, and channel quality measurements.
Node B 110 may further interface with UE 120 via radio link connection 130. The LTE physical layer includes Orthogonal Frequency Division Multiple Access (OFDMA) and multiple input and multiple output (MIMO) data transmission. For example, in LTE, OFDMA is used for downlink transmission and single carrier frequency division multiple access (SC-FDMA) is used for uplink transmission. Since the transmission frequency band is divided into a plurality of subcarriers orthogonal to each other in OFDMA, each subcarrier can transmit data to a specific UE 120. As a result, multiple access is achieved by assigning a subset of subcarriers to individual UEs 120. However, SC-FDMA is a form of discrete Fourier transform (DFT) precoded OFDMA scheme. Therefore, SC-FDMA can use single carrier modulation, orthogonal frequency domain multiplexing, and frequency domain equalization.
Node B 110 typically includes an antenna (not shown) connected to a number of components including a power amplifier and a digital signal processor (not shown). Node B 110 may serve a number of cells 101, also referred to as sectors, based on antenna configuration and type.
Continuing with FIG. 1, UE 120 is a device that roughly corresponds to a mobile station in the GSM system and is used directly by end users for communication. For example, UE 120 may be a handheld phone, a laptop computer card, or other device. The UE 120 is connected to the base station, ie, the Node B 110 described above specified in the 36 series specification. This roughly corresponds to a mobile station in the GSM system.
Further, as described in detail below, UE 120 sends and receives a number of messages to Node B 110. As will be described below, one of the messages sent includes the SRS 102. SRS 102 may be configured based on data received from Node B 110, data received by a user interface, or both. As a result, a message including the SRS 102 can be transmitted from the UE 120 to the Node B 110.
UE 120 typically handles tasks including mobility management, call control, session management, and identity management towards the core network. In general, the corresponding protocol is transmitted transparently through Node B 110 so that Node B 110 does not change, use or understand the protocol information. The UMTS backend includes GSM / UMTS radio networks (GSM Edge Radio Access Network (GERAN), UMTS Terrestrial Radio Access Network (UTRAN), and Evolved Universal Terrestrial Radio Access Network (E-UTRAN)), WiFi, Ultra Mobile Broadband ( UMB) and access via various means such as microwave interoperability for world wide interoperability (WiMAX). Non-UMTS wireless network users are given entry points into the IP network at different security levels based on the reliability of the network used to make the connection. GSM / UMTS network users can use an integrated system where all authentications at each level of the system are covered by a single system. However, users can access the UMTS network via WiMAX and other similar technologies to handle WiMAX connections in some way, eg authenticate themselves via Media Access Control (MAC), or electronic serial numbers (ESN) addresses and UMTS linkups can be handled differently.
In LTE, Release 8, an air interface called Evolved Universal Terrestrial Radio Access (E-UTRAN) can be used by UMTS operators deploying wireless networks. Although E-UTRA is still being refined, current E-UTRA systems use orthogonal frequency division multiple access (OFDMA) for the downlink (tower to handset) and simple for the uplink. It uses single carrier frequency division multiple access (SC-FDMA) and multiple inputs / multiple outputs (MIMO) with up to 4 antennas per station. The channel coding scheme for the transport block is turbo coding and contention free second order permutation polynomial (QPP) turbo code internal interleaver.
By using Orthogonal Frequency Division Multiplexing (OFDM), ie using a system that divides the available spectrum into thousands of very thin carriers, each at a different frequency and each carrying a portion of the signal Thus, E-UTRA can have much more flexibility in spectrum usage than older CDMA-based systems used for 3G protocols. CDMA networks typically require a large block of spectrum to be assigned to each carrier in order to maintain a high chip rate and thus maximize efficiency. OFDM has a higher link spectrum efficiency than CDMA, and when compared to modulation formats like 64QAM and technologies like MIMO, E-UTRA typically has high-speed downlink packet access (HSDPA) and More efficient than W-CDMA with high speed uplink packet access (HSUPA).
In LTE Release 8, the OFDM downlink subcarrier spacing is 15 kHz, and a maximum of 2048 subcarriers can be used. The mobile device must be able to receive a total of 2048 subcarriers, but the base station need only support the transmission of 72 subcarriers. The transmission is divided in time into 0.5 ms wide time slots and 1.0 ms wide subframes. The radio frame is 10 ms long. The modulation formats supported for the downlink data channel are quadrature phase shift keying (QPSK), 16 quadrature amplitude modulation (QAM), and 64QAM.
Continuing with the current specification for the uplink, SC-FDMA multiplexing is used and QPSK or 16QAM (or 64QAM) modulation is used. SC-FDMA is used because of its low peak-to-average power ratio (PAPR). Each mobile device comprises at least one transmitter. With virtual MIMO / space division multiple access (SDMA), the system capacity in the uplink direction can be reduced based on the number of antennas in the base station.
In particular, the LTE uplink transmission scheme typically uses SC-FDMA. Although OFDMA turns out to be optimal to satisfy LTE requirements in the downlink, the OFDMA characteristics are not very advantageous for the uplink. This is mainly due to the weak peak-to-average power ratio (PAPR) characteristics of the OFDMA signal, resulting in poor uplink coverage. Thus, the LTE uplink transmission scheme for frequency division multiplexing (FDD) and time division duplex (TDD) modes is based on SC-FDMA (Single Carrier Frequency Division Multiple Access) with cyclic prefix. SC-FDMA signals have superior PAPR characteristics compared to OFDMA signals, and PAPR characteristics are important for the cost effective design of UE power amplifiers. Still, SC-FDMA signal processing has some similarity to OFDMA signal processing and thus can coordinate downlink and uplink parameterization.
There may be differences in how the SC-FDMA signal is generated. For example, when discrete Fourier transform spread orthogonal frequency division multiplexing (DFT-S-OFDM) is selected for E-UTRA, first a size M DFT is applied to a block of M modulated signals. QPSK, 16QAM and 64QAM are then used as the uplink E-UTRA modulation scheme, the latter being optional for UE 120. DFT transforms the modulated signal into the frequency domain. The result is mapped to available subcarriers. In the E-UTRA uplink, only localized transmissions on continuous subcarriers are allowed. If N> M, an N-point inverse fast Fourier transform (IFFT) is performed as in OFDMA, and then cyclic prefix addition and parallel / serial conversion are performed.
Therefore, DFT processing is the fundamental difference between SCFDMA signal generation and OFDMA signal generation. This is indicated by the word “DFT spread OFDM”. In the SC-FDMA signal, each subcarrier used for transmission includes information of all modulated signals to be transmitted. This is because the input data stream is spread over the available subcarriers by DFT transformation. In contrast, each subcarrier of an OFDMA signal carries only information related to a particular modulation symbol.
Similarly, in SC-FDMA parameterization, the E-UTRA uplink structure is similar to the downlink. For example, an uplink radio frame consists of 20 slots of 0.5 ms each, and one subframe consists of 2 slots. In the uplink, data is allocated in multiples of one resource block. The uplink resource block size in the frequency domain is 12 subcarriers, that is, the same as the downlink. However, not all integer multiples are allowed to simplify DFT design in uplink signal processing, typically only factors 2, 3 and 5 are allowed. The uplink transmission time interval is 1 ms (same as downlink).
User data is carried over the physical uplink shared channel (PUSCH), which is determined by the start resource block, the transmission bandwidth, and the frequency hopping pattern when PUSCH hopping is enabled. The physical uplink control channel (PUCCH) carries uplink control information in the absence of UL data, eg, CQI reports and ACK / NACK information associated with data packets received on the downlink (if UL data is present). The control signal is multiplexed with the UL data and transmitted at PUSCH time). The PUCCH is transmitted in the uplink reserved frequency domain.
In the uplink reference signal structure, the uplink reference signal is used for channel estimation at the receiver of Node B 110 to demodulate the control and data channels. On the other hand, the reference signal provides channel quality information as a basis for scheduling decisions at the base station (ie, Node B 110), which is also referred to as channel sounding. The uplink reference signal is based on a CAZAC (constant amplitude zero autocorrelation) sequence or a computer search based ZAC sequence.
The uplink physical layer procedure with E-UTRA requires an uplink physical layer procedure. For example, in asynchronous random access, random access is used to request initial access as part of handover when transitioning from idle state to connected state, or to re-establish uplink synchronization. Similarly, multiple random access channels can be defined in the frequency domain within one access period to provide a sufficient number of random access opportunities.
The random access procedure uses open loop power control with a power ramp similar to WCDMA. After transmitting the preamble via the selected random access channel, the UE 120 waits for a random access response message. If no response is detected, another random access channel is selected and the preamble is transmitted again.
For uplink scheduling, uplink resource scheduling is performed by the Node B 110. Node B 110 assigns certain time / frequency resources to UE 120 and informs UE 120 which transmission format to use. Scheduling decisions that affect dynamically scheduled uplinks are communicated to UE 120 via PDCCH in the downlink. Upper layer signaling can also be used, for example, in the case of persistent scheduling. Scheduling decisions are based on quality of service (QoS) parameters, UE buffer status, uplink channel quality measurements, UE capabilities, UE measurement gaps, and so on.
Uplink link adaptation methods, transmit power control, adaptive modulation and channel coding rates, and adaptive transmit bandwidth can be used. Similarly, uplink timing control is required to time align transmissions from different UEs 120 with the reception window of Node B 110. Node B 110 sends appropriate timing control commands on the downlink to UE 120 and instructs UE 120 to adapt each transmission timing. In the case of a hybrid automatic repeat request (ARQ), the Node B 110 can request retransmission of a data packet received in error.
The 3.9th generation mobile phone technology provides a digital mobile phone system based on 3G but with expansion capabilities close to 4G expectations. Feasibility and standardization are being studied with the goal of achieving a smooth transition link between current 3G and future 4G.
Referring to FIG. 3, an SRS configuration 300 according to one embodiment is shown. For example, FIG. 3 shows an embodiment for generating an SRS bandwidth tree. More particularly, FIG. 3 illustrates a subset of supported SRS bandwidth according to some embodiments. In all cases of SRS configuration 300, the minimum SRS bandwidth is limited to 4 RBs. Furthermore, in these specific examples, two to four SRS bandwidth options are provided for channel bandwidths greater than 1.6 MHz.
Continuing with FIG. 3, in the SRS configuration 300, although optional, at least two separate sets of SRS bandwidths are proposed for each of the large operating bandwidths, eg, greater than 10 MHz. The For example, the first bandwidth 310 has a large margin for PUCCH and persistent PUSCH, leaving a maximum SRS bandwidth of about 80% of the total BW. In contrast, the second set of SRS bandwidths 320 is configured with a small margin for PUCCH and persistent PUSCH and has a maximum SRS bandwidth of up to 96% of the total BW. The first bandwidth 310 is used in the embodiment for a large margin reserved for PUCCH and persistent PUSCH. It should also be noted that the final decision on the number of SRS bandwidth schemes depends on the handling of dynamically changing PUCCH bandwidth (BW), as described in detail below.
More specifically, the actual amount of cyclic shift of a symbol can be calculated based on Equation 1 below related to the time domain occurrence of cyclic shift.
However, possible cyclic shift values (cyclic_shift_value_SRS) are 0, 1,. The corresponding cyclic shift can be generated by using the basic properties of the discrete Fourier transform, i.e., a cyclic shift of 1 means that exp (j2πln / N), where j = sqrt (−1), and N is the length of the sequence. Therefore, the cyclic shift of Equation 1 can be realized by multiplying the nth element of the sequence SRS discrete Fourier transform by exp (j2πn × cyclic_shift_symbols_SRS / SRS_length) = exp (j2πn × cyclic_shift_value_SRS / 8) in the frequency domain. .
More specifically, in the SRS bandwidth configuration 300 shown in FIG. 3, it will be apparent that SRS signaling handling BW allocation and cyclic shift designation is based on the following characteristics:
● 1-2 (N) bits included to signal selected SRS bandwidth ● C bits included to signal bandwidth position in code tree ● Selected for SRS signals of different bandwidth 3 bits included to signal a cyclic shift • Probably also includes M bits to indicate the frequency position of the code tree
As described above, the SRS configuration is generated based on three criteria. For example, the SRS signal is based on an existing DM RS signal as defined by LTE, Release 8. In particular, as described above, the general description of 3GPP LTE requires that the size of the discrete Fourier transform (DFT) corresponding to the number of allocated RUs * 12 be factored into a small number of prime numbers. As a result, efficient implementation of DFT-S-OFDM is successfully achieved. DFT in LTE size is limited to multiples of primes 2, 3 and 5. With respect to SRS, recent versions of the LTE protocol further include a requirement to always use a repetition factor of 2 (RPF) to allow the DM RS sequence to be reused with the SRS.
In view of these additional requirements, an example of bandwidth options supported in this embodiment is shown in table 400 of FIG. In particular, table 400 includes a column of possible PUSCH resource allocation sizes for resource blocks (RBs) and a second column that indicates that the corresponding SRS BW is allowed in view of the above-described requirements. For example, bandwidth allocation with an odd number of RBs is not supported in SRS to require that one of the RPFs be equal to 2. However, the table 400 of FIG. 4 is prescriptive in view of the above conditions and uses additional SRS bandwidth sizes based on additional / change requirements specified for future communications. Obviously you can.
Furthermore, the current LTE specifies that maximum cyclic shift separation is provided for 8 parallel cyclic shifts. In particular, as described above, the cyclic shift of the SRS sequence is currently indicated by 3 bits. However, conventional techniques that use 3 bits to represent cyclic shifts do not maximize the cyclic shift separation between SRS resources.
Therefore, in another embodiment, the length of the SRS depends on the SRS bandwidth, which is a multiple of the number of RBs consisting of 12 frequency pins. Therefore, the sequence length is given as 12 / RPF multiplied by the number of RUs (RPF = 2). Therefore, the maximum separation between 8 cyclic shifts is the SRS sequence length that can be divided by 8, which occurs when SRS BW is a multiple of 4 RBs. Accordingly, the table 500 of FIG. 5 further modifies the table 400 to accept only the number of RBs that can be divided by 8. As a result, table 500 specifies an acceptable SRS bandwidth that supports eight simultaneous resources to achieve the desired maximum cyclic shift separation, as shown in Equation 1.
It is further desirable to provide support for code tree-based bandwidth specification, referring to the third criteria described above for the desired SRS configuration. In particular, as described above, narrowband and wideband SRS BW can be supported for a given operating bandwidth. The different operations BW of E-UTRA are listed in the top row of the table 600 of FIG. 6, which correspond to the transmission bandwidth configuration N EA of the E-UTRA channel bandwidth. Based on the above-mentioned conditions, when considering wideband SRS, the two SRBs reserved for PUCCH are subtracted from the SRS bandwidth, which is preferably limited by the number of RBs in a given channel bandwidth, and the SRS To help protect against puncturing of the PUCCH region due to transmission.
Referring to the table 700 of FIG. 7, when selecting the SRS bandwidth, compatibility with OVSF-based code designation can also be considered. In particular, the table 700 shows an example configuration for SRS bandwidth, where the size of the upper row, eg, row 710 (shown in the left column) is the smaller SRS bandwidth in any lower row. Any of the widths 720, 730 and 740 can be divided uniformly. As a result, each large BW option can be divided by any of the narrow BW options, thus providing support for tree-based bandwidth specification.
Furthermore, compatibility with OVSF-based codes is improved through the above-described properties of SRS assignment achieved by the principles of this embodiment. In particular, in addition to supporting code trees, this SRS assignment configuration is built using existing DM RS signals, providing maximum cyclic shift separation for 8 cyclic shifts.
In some embodiments, maximum cyclic shift separation is provided between adjacent cyclic shift (CS) resources while supporting code tree based bandwidth designation for signaling save. At the same time, existing DM RSs can continue to be used to avoid adding additional sounding only reference signals. At the same time, the embodiments disclosed herein provide optimal estimation accuracy.
In another embodiment, a minimum SRS bandwidth is provided. For example, possible values for the minimum SRS bandwidth include 2RB and 4RB, as shown in the SRS bandwidth table 400 of FIG. Therefore, the minimum SRS bandwidth is basically defined by the sounding error, not the channel bandwidth. As shown in FIGS. 10A and 10B, charts 1000 and 1010 compare sounding errors between 2RB and 4RB sounding reference signals. In particular, the chart 1000 of FIG. 10A corresponds to the expected value of the signal to interference plus noise ratio (SINR) estimator, while the chart 1010 of FIG. 10B illustrates the signal to noise ratio (SNR) as a function of the input SINR. ) Standard deviation. These measurements generally suggest that there is no significant difference in sounding accuracy, even at the 3 dB high power spectral density of the 2RB sounding signal. This result is due to the fact that with a 4 RB signal, a wide processing gain can be used to compensate for the low power spectral density. Thus, in one embodiment, the minimum SRS bandwidth is 4 RBs to provide sufficient sounding quality while relaxing signal power requirements.
Referring to FIG. 8, a process flowchart 800 according to some embodiments is shown. In particular, the flowchart 800 illustrates the interaction between the Node B 110, the UE 120, and the user 125. The UE 820 receives Radio Resource Control (RRC) signaling 840 that is SRS configuration signaling. This signaling can be dedicated (UE specific) or broadcast (cell specific system information). UE 820 optionally receives configuration data 850 from user 125 that describes the desired configuration settings. UE 820 uses data 840 and 850 to generate an uplink message 860 to Node B 110 that includes the SRS assignments disclosed herein. Node B 110 may then respond with a UL scheduling grant 870 signaled via DL (eg, PDCCH) in response to the request by UE 120 in uplink message 860. In response to the UL scheduling grant in UL message 870, UE 120 may forward UL data transmission 880 for which a link adaptation / scheduling decision has been made based on the transmitted SRS to Node B 110. Alternatively, the Node B 110 (eg, eNB) may be configured to send a UL power control (PC) command or timing adjustment command / update to the UE 120. However, Node B 110 may be configured not to transmit based on SRS measurements if there is no reason for signaling. It will be apparent that these signals are transmitted using dynamic control signaling, eg, DCI format 0, dedicated RRC signaling.
With reference to FIGS. 9A-9B, a method 900 configured to provide the SRS BW allocation described above will be described. In particular, the SRS BW allocation method 900 includes a step 910 of biasing the SRS signal in an existing DM RS signal. Then, in step 920, an SRS BW configuration can be created to provide maximum cyclic shift separation. Then, in step 930, an SRS BW configuration can be selected to support code tree-based bandwidth specification.
As shown in FIG. 9B, step 910 of biasing the SRS signal in the existing DM RS signal includes a step 911 of reserving sufficient bandwidth for the PUCCH and persistent PUSCH. The step 910 of biasing the SRS signal in the existing DM RS signal further includes a step 912 of adapting the SRS bandwidth allocation based on the desired DFT and repetition factor (RPF) size.
With reference to FIG. 2, a UE 120 according to some embodiments will be described. The UE 120 includes a processor 220, an interface (ie, user input 210), a transmitter 240, a receiver 250, and a data storage device 230. Are details associated with DM RS signals, the desired maximum cyclic shift separation, and details to support code tree based bandwidth designation received from receiver 250 from another source (ie, base station)? , Or input by the user interface 210, or both. This data received via the receiver or by the user interface 210 is then stored in the storage device 230. The processor 220 can be configured to access data stored in the storage device 230 to form an uplink message that includes the SRS. In addition, the storage device 230 allows the processor 220 to determine sufficient bandwidth to reserve for the PUCCH and persistent PUSCH and the corresponding desired DFT and RPF sizes for SRS bandwidth allocation. Additional data can be stored as needed. This additional data stored in the storage device 230 may also be provided by, for example, the user interface 210 and / or received from the external source (ie, base station) via the receiver 250, or both. is there. The processor 220 then forms an uplink message containing the SRS bandwidth allocation (using a predetermined cyclic shift) and forwards this uplink message to the transmitter 240, as shown in FIG. To an external device such as a node B.
However, as noted above, SRS transmissions should not “puncture” the PUCCH region or otherwise attempt to transmit via the RB reserved for the PUCCH. Similarly, in some cases, the SRS does not puncture persistent PUSCH assignments. Therefore, another embodiment relates to satisfying the requirement that SRS transmissions should not puncture the PUCCH region even in cases where the PUCCH bandwidth (BW) including persistent PUSCH changes dynamically.
Referring to FIG. 11, a method 1100 for handling dynamically changing PUCCH BW is shown. In step 1110, the SRS transmission is prevented from puncturing the PUCCH region by reconfiguring the SRS transmission to avoid PUCCH puncturing. Since SRS reconfiguration typically requires a relatively long time and a significant amount of signaling, especially if a large number of UEs require SRS reconfiguration, step 1110 shown in FIG. A changing PUCCH BW may not be sufficient.
As a result, FIG. 11 shows a method 1100 for handling dynamically changing PUCCH BWs by continuing to broadcast information about RBs, where SRS transmission is not allowed in step 1120. More specifically, the broadcast specifies that SRS transmission is not allowed in the RB allocated for the PUCCH region. Then, in step 1130, the SRS is cut when the SRS is superimposed on a bandwidth that does not support SRS transmission. Typically, the UE autonomously performs the cutting of step 1130 using conventional techniques without requiring additional UE-specific signaling. The SRS is cut towards the maximum allowed SRS BW in step 1131. The supported SRS BW options are listed in the rightmost column of the table 500 described above in the description of FIG. In one embodiment, in step 1132, only the outermost SRS signal is cut. As a result, the cut does not affect the configured SRS BW (40 RB, 20 RB, and 4 RB in the example table 1200 shown in FIG. 12 and described in detail below) and the applied code tree based bandwidth. Does not affect the specification.
Thus, the handling of dynamically changing PUCCH BWs in method 1100 provides an actual solution to be addressed when PUCCH and / or persistent PUSCH BW changes dynamically. As described above, the SRS is cut towards the maximum allowable SRS BW. The cut SRS BW is a member of an existing DM RS set, and the SRS BW is a multiple of 4 RBs.
Referring to the table 1200 of FIG. 12, an example method 1100 for handling dynamically changing PUCCH BWs is shown. This example of table 1200 assumes a channel bandwidth of 10 MHz. As described above in the SRS bandwidth table 300 of FIG. 3, approximately 80% of the total BW available when reserving large margins for PUCCH and persistent PUSCH using the first bandwidth 310 scheme. , The SRS BW set includes three SRS bandwidths of 40 RB, 20 RB, and 4 RB, and this SRS allocation set corresponds to the original SRS BW set 1210. In this example, in the table 1200, the original BW set 1210 is cut. This is because the PUCCH region 1220 is superimposed on the SRS BW set 1210. To address this issue, according to the method 1100 for handling dynamically changing PUCCH BW, the SRS BW set is cut (1230). In particular, as shown in the rightmost column of the table 500 in FIG. 5, the SRS is cut toward the maximum allowable SRS BW (32 in the display example of the table 1200) by the step 1131.
As shown in table 1200 of FIG. 12, the handling of dynamically changing PUCCH BWs in method 1100 maintains a code tree based SRS bandwidth designation that is beneficial from a signaling perspective, for example, in the context of frequency hopping SRS. Including many things. Furthermore, the additional signaling burden is very small. This is because the bandwidth required for signaling the number of RBs that do not support SRS transmission is very small. Furthermore, the handling of SRS / PUCCH is specific to the implementation. This is because the operator can control the area where the SRS can be transmitted to optimize the persistent PUSCH, and the method 1200 is relatively small such as the cutting rules and the code tree based SRS designation applied. This is because only the items are specified. The resulting specification is therefore relatively easy to define (single SRS BW set / system BW).
For persistent PUSCH, cutting the SRS transmission that overlaps the unsupported RB bandwidth in step 1130 includes defining regions where no SRS is transmitted toward the two ends of the BW. Thus, in general, the persistent assignment must be in that region and the dynamic PUSCH UE must be in the region where the SRS is transmitted. Alternatively, to reduce SRS overhead, one bit of the UL grant can inform whether the SRS symbol is available for data transmission or whether it is used by the SRS.
Some embodiments may include a computer program implemented on a computer readable medium, the computer readable medium encoded in a computer program or similar language being a processor, a digital processing device, a central processing unit (CPU), etc. can easily be implemented as a tangible data storage device that stores computer software programs configured to perform one or more operations or execute one or more software instructions It will be clear to The tangible data storage device may be implemented as a volatile memory device or a non-volatile memory device, and / or may be implemented as a combination of a volatile memory device and a non-volatile memory device. Accordingly, some embodiments provide a computer readable medium encoded with a computer program configured to perform operations.
One skilled in the art will readily appreciate that some of the embodiments described above can be implemented in a different order of steps and / or with differently configured hardware elements than those disclosed herein. Thus, although several embodiments have been described based on various configurations, those skilled in the art will recognize numerous changes, modifications, and alternatives without departing from the spirit and scope of the several embodiments described above. The structure will be clear. Therefore, reference should be made to the claims to determine the boundaries and ranges of some embodiments.
Throughout this specification, a description of a feature, effect, or similar expression does not imply that all features and effects realized in some embodiments must be in one embodiment. Please be careful. Rather, expressions referring to features and effects are understood to mean that a particular feature, effect, or characteristic described in connection with an embodiment is included in at least one embodiment described above. Accordingly, descriptions of features and effects throughout the specification, and similar expressions, may, but need not, refer to the same embodiment.
Furthermore, the features, advantages, and characteristics shown herein in some embodiments may be combined as appropriate in one or more embodiments. It will be apparent to those skilled in the art that several embodiments can be implemented without one or more specific features or effects of the specific embodiments. In other examples, additional features and effects that are not present in all embodiments may be identified in certain embodiments.
100: UMTS system 101: Cell 110: Node B
120: User equipment (UE)
130: UU
200: UE
210: User input 220: Processor 230: Data storage device 240: Transmitter 250: Receiver
Generating an uplink message to be transmitted to the base station, wherein the generated uplink message includes a sounding reference signal based on the accessed data;
Receiving an uplink scheduling grant signal via a downlink from a base station in response to transmission of the uplink message;
Transmitting an uplink data transmission to a base station in response to the received uplink scheduling grant signal;
Storing data associated with the reference signal sequence, forming a desired cyclic shift separation between the reference signal sequences, and supporting tree-based bandwidth designation, the data from a user interface or base station The method of claim 1, further comprising the step of being received.
Forming the sounding reference signal based on an existing demodulated reference signal;
Selecting the sounding reference signal to support tree-based bandwidth specification;
Adapting the sounding reference signal to provide maximum cyclic shift separation;
Reserving sufficient bandwidth for at least a physical uplink control channel when forming the sounding reference signal based on an existing demodulated reference signal signal;
Selecting bandwidth allocation based on a discrete Fourier transform and repetition factor size when forming the sounding reference signal based on an existing demodulated reference signal signal;
Configuring a maximum cyclic shift separation between eight cyclic shifts to produce a sounding reference signal sequence length that can be divided by eight when the bandwidth of the sounding reference signal is a multiple of four resource blocks;
The method of claim 4, further comprising the step of determining a bandwidth sufficient to reserve for a physical uplink control channel.
The method of claim 5, further comprising configuring at least two resource blocks to be reserved for a physical uplink control channel.
5. The method of claim 4, wherein the demodulated reference signal signal includes a desired discrete Fourier transform and repetition factor size, and the discrete Fourier transform size is 2, 3 or 5.
4. The method of claim 3, further comprising supporting the tree-based bandwidth designation based on a selection of a sounding reference signal bandwidth that can uniformly divide a large bandwidth by a small bandwidth.
The method of claim 3, wherein a cyclic shift separation between possible cyclic shifts is maximized, and wherein the cyclic shift is based on a sequence length and the number of possible cyclic shifts.
The cyclic shift is the cyclic shift indicator received from the base station multiplied by the sequence length and divided by the number of possible cyclic shifts, and the number of possible cyclic shifts is: The method of claim 9, wherein the method is 8.
The method of claim 1, wherein a bandwidth of the sounding reference signal includes a minimum of 4 resource blocks.
Equation 1 related to the time domain occurrence of a cyclic shift, ie,
However, possible cyclic shift values (cyclic_shift_value_SRS) are 0, 1,... 7
The method of claim 1, further comprising: using to calculate the actual amount of cyclic shift in the symbol.
Generating a corresponding cyclic shift by utilizing the basic properties of the discrete Fourier transform;
The step of generating one cyclic shift by multiplying the nth element of the sequence discrete Fourier transform by exp (j2πln / N), where j = sqrt (−1) and N is the length of the sequence. When,
Multiplying the nth element of the SRS sequence discrete Fourier transform by exp (j2πn x cyclic_shift_symbols_SRS / SRS_length) = exp (j2πn x cyclic_shift_value_SRS / 8) to realize the cyclic shift of Equation 1 in the frequency domain; ,
Receiving an uplink message comprising a sounding resource signal allocation bandwidth from a mobile station;
Transmitting an uplink scheduling grant signal to the mobile station via the downlink;
Receiving an uplink data transmission from the mobile station in response to the transmitted uplink scheduling grant signal;
The method of claim 14, further comprising configuring an uplink message to include a reserved bandwidth for a physical uplink control channel.
The method of claim 16, further comprising configuring two resource blocks to be reserved for a physical uplink control channel.
15. The method of claim 14, wherein the demodulated reference signal signal comprises a desired discrete Fourier transform and a repetition factor size of 2, 3 or 5.
15. The method of claim 14, further comprising supporting the tree-based bandwidth designation based on a sounding reference signal bandwidth selection that can uniformly divide a large bandwidth by a small bandwidth.
The method of claim 14, wherein a cyclic shift separation between possible cyclic shifts is maximized, and the cyclic shift is based on a sequence length and the number of possible cyclic shifts.
The method of claim 14, further comprising providing a minimum sounding reference signal bandwidth having four resource blocks.
A transmitter configured to transmit a generated uplink message including a sounding reference signal to a base station;
A receiver configured to receive an uplink scheduling grant signal from the base station via the downlink;
And the transmitter is further configured to transmit an uplink data transmission to the base station in response to the received uplink scheduling grant signal.
Storing data associated with the reference signal sequence, forming a desired cyclic shift separation between the reference signal sequences, and further comprising a storage device configured to support tree-based bandwidth designation, the data comprising: 23. The apparatus of claim 22, wherein the apparatus is received from a user interface or base station.
Selecting the sounding reference signal to support tree-based bandwidth specification and adapting the sounding reference signal to provide maximum cyclic shift separation;
23. The apparatus of claim 22 configured as follows.
Reserve sufficient bandwidth for the physical uplink control channel when forming the sounding reference signal based on an existing demodulated reference signal signal;
Selecting a bandwidth allocation based on a discrete Fourier transform and repetition factor size when forming the sounding reference signal based on an existing demodulated reference signal signal, and the bandwidth of the sounding reference signal is equal to four resource blocks Maximize the cyclic shift separation between the 8 cyclic shifts to produce a sounding reference signal sequence length that can be divided by 8 when it is a multiple;
25. The apparatus of claim 24 configured as follows.
26. The apparatus of claim 25, wherein the processor is further configured to determine a bandwidth sufficient to reserve for a physical uplink control channel.
27. The apparatus of claim 26, wherein two resource blocks are reserved for a protocol uplink control channel.
26. The apparatus of claim 25, wherein the demodulated reference signal signal includes a desired discrete Fourier transform and repetition factor size, and the discrete Fourier transform size is 2, 3 or 5.
25. The apparatus of claim 24, wherein the processor is further configured to support the tree-based bandwidth designation based on a selection of a sounding reference signal bandwidth that can uniformly divide a large bandwidth by a small bandwidth. .
25. The apparatus of claim 24, wherein a cyclic shift separation between possible cyclic shifts is maximized, and wherein the cyclic shift is based on a sequence length and the number of possible cyclic shifts.
The cyclic shift is the cyclic shift indicator received from the base station multiplied by the sequence length and divided by the number of possible cyclic shifts, and the number of possible cyclic shifts is: 32. The device of claim 30, wherein the device is eight.
23. The apparatus of claim 22, wherein a bandwidth of the sounding reference signal includes a minimum of 4 resource blocks.
23. The apparatus of claim 22, further comprising a calculator configured to calculate an actual amount of cyclic shift in a symbol using.
A generator configured to generate a corresponding cyclic shift by utilizing the basic properties of a discrete Fourier transform;
Assuming that j = sqrt (−1) and N is the length of the sequence, a cyclic shift of 1 is generated by multiplying the nth element of the sequence discrete Fourier transform by exp (j2πln / N). With another generator configured in
Multiplying the nth element of the SRS sequence discrete Fourier transform by exp (j2πn × cyclic_shift_symbols_SRS / SRS_length) = exp (j2πn × cyclic_shift_value_SRS / 8) so as to realize the cyclic shift of Equation 1 in the frequency domain A configured realization unit; and
A receiver configured to receive an uplink message including a sounding resource signal allocation bandwidth;
A transmitter configured to transmit an uplink scheduling grant signal to the mobile station via the downlink;
And the receiver is further configured to receive an uplink data transmission from the mobile station in response to the transmitted uplink scheduling grant signal.
The sounding reference signal is formed based on an existing demodulated reference signal signal, selected to support tree-based bandwidth specification, and configured to be adapted to provide maximum cyclic shift separation 36. The apparatus of claim 35.
36. The apparatus of claim 35, wherein the uplink message is configured to include a bandwidth reserved for a physical uplink control channel.
38. The apparatus of claim 37, wherein two resource blocks are reserved for a protocol uplink control channel.
36. The apparatus of claim 35, wherein the demodulated reference signal signal is configured to include a desired discrete Fourier transform and a repetition factor size of 2, 3 or 5.
36. The apparatus of claim 35, wherein the tree-based bandwidth designation is configured to be supported based on a selection of a sounding reference signal bandwidth that can uniformly divide a large bandwidth with a small bandwidth.
36. The apparatus of claim 35, wherein the cyclic shift separation between possible cyclic shifts is maximized, and wherein the cyclic shift is based on a sequence length and the number of possible cyclic shifts.
36. The apparatus of claim 35, wherein providing a minimum sounding reference signal is configured to be provided with a minimum of 4 resource blocks.
Transmitting means for transmitting the generated uplink message including the sounding reference signal to the base station;
Receiver means for receiving an uplink scheduling grant signal from the base station via the downlink;
And wherein the means for transmitting transmits the uplink data transmission to the base station in response to the received uplink scheduling grant signal.
Receiving means for receiving an uplink message including a sounding resource signal allocation bandwidth;
Transmitting means for transmitting an uplink scheduling grant signal to the mobile station via the downlink;
And wherein the receiving means receives an uplink data transmission from the mobile station in response to the transmitted uplink scheduling grant signal.
In a computer program implemented on a computer-readable medium,
Generating an uplink message to be transmitted to the base station, the uplink message including a sounding reference signal based on the accessed data;
Transmitting an uplink data transmission to the base station in response to the received uplink scheduling grant signal;
A computer program configured to control a process for performing a method comprising:
Receiving an uplink message including a sounding resource signal allocation bandwidth;
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