The present disclosure relates to a wireless communication system. More particularly, the present disclosure relates to a method and device for transmitting an OFDM signal, and a method and device for receiving an OFDM signal.
In a mobile communication system, a transmitting device typically generates a baseband signal, up-converts the baseband signal to a higher carrier frequency, and transmits an up-converted radio signal at the carrier frequency. A receiving device then receives the radio signal, and down-converts the received radio signal from the carrier frequency to a lower baseband frequency to obtain a baseband signal for further processing.
If the information about the frequency for upconversion is unknown to the transmitting device and the receiving device, mismatch may occur between the upconversion frequency used by the transmitting device and the downconversion frequency used by the receiving device. The mismatch between the upconversion frequency and the downconversion frequency causes a sudden phase change in each time symbol in the receiving device. Such a sudden phase change greatly degrades performance of signal recovery by channel estimation in the receiving device. Therefore, a method for reducing the phase change in each symbol caused by mismatch between the upconversion frequency and the downconversion frequency, mismatch between the carrier frequency and the center frequency of the frequency band, or mismatch between the carrier frequency and the center of the RF filter is required.
In addition, when the carrier frequency changes in the same frequency band, a method of easily adjusting the carrier frequency without RF retuning is required.
The object of the present disclosure can be achieved by techniques disclosed herein for transmitting an orthogonal frequency division multiplexing (OFDM) signal by a transmitting device in a wireless communication system. In one aspect, provided herein is a method of transmitting, by a transmitting device, an orthogonal frequency division multiplexing (OFDM) signal in a wireless communication system. The method comprises: generating, by a digital module of the device, a frequency-shifted OFDM baseband signal by performing frequency up-shift of a first signal by a difference between a carrier frequency f0 and a first frequency fbase; up-converting, by an analog oscillator of the device, the frequency-shifted OFDM baseband signal by the first frequency fbase to generate an OFDM symbol signal at the carrier frequency f0; and transmitting, by a transmitter of the device, the OFDM symbol signal at the carrier frequency f0. The first frequency fbase may be, among frequencies corresponding to integer multiples of 128Δf, closest to the carrier frequency f0. Δf is an OFDM subcarrier spacing.
In another aspect, provided herein is a method of receiving, by a device at a receiving side, an orthogonal frequency division multiplexing (OFDM) signal in a wireless communication system. The method comprises: receiving an OFDM symbol signal at a carrier frequency f0; down-converting, by an analog oscillator of the device, the OFDM symbol signal by a first frequency fbase to generate a down-converted OFDM symbol signal; and generating, by a digital module of the device, an OFDM baseband signal by performing frequency down-shift of the down-converted OFDM symbol signal by a difference between the carrier frequency f0 and fbase. The first frequency fbase may be, among frequencies corresponding to integer multiples of 128Δf, closest to the carrier frequency f0. Δf is an OFDM subcarrier spacing.
In a further aspect, provided herein is a device at a transmitting side for transmitting an orthogonal frequency division multiplexing (OFDM) signal in a wireless communication system.
The device may comprise: a digital module; an analog oscillator; at least one antenna; at least one processor; and at least one computer memory that is operably connectable to the at least one processor and that has stored thereon instructions which, when executed, cause the at least one processor to perform operations. The operations may comprise: generating, by the digital module, a frequency-shifted OFDM baseband signal by performing frequency up-shift of a first signal by a difference between a carrier frequency f0 and a first frequency fbase: up-converting, by the analog oscillator, the frequency-shifted OFDM baseband signal by the first frequency fbase to generate an OFDM symbol signal at the carrier frequency f0; and transmitting, using the at least one antenna, the OFDM symbol signal at the carrier frequency f0. The first frequency fbase may be, among frequencies corresponding to integer multiples of 128Δf, closest to the carrier frequency f0. Δf is an OFDM subcarrier spacing.
In a still further aspect, provided herein is a device at a receiving side for receiving an orthogonal frequency division multiplexing (OFDM) signal in a wireless communication system. The device may comprise: at least one antenna; an analog oscillator; a digital module; at least one processor; and at least one computer memory that is operably connectable to the at least one processor and that has stored thereon instructions which, when executed, cause the at least one processor to perform operations. The operations may comprise: receiving, using the at least one antenna, an OFDM symbol signal at a carrier frequency f0; down-converting, by the analog oscillator, the OFDM symbol signal by a first frequency fbase to generate a down-converted OFDM symbol signal; and generating, by the digital module, an OFDM baseband signal by performing frequency down-shift of the down-converted OFDM symbol signal by a difference between the carrier frequency f0 and fbase. The first frequency fbase may be, among frequencies corresponding to integer multiples of 128Δf, closest to the carrier frequency f0. Δf is an OFDM subcarrier spacing.
In each aspect at the transmitting side, the digital module may be configured to implement an inverse fast Fourier transform (IFFT) on the first signal.
In each aspect of a transmitting side, performing the frequency up-shift of the first signal by the difference between f0 and fbase may comprise: up-shifting, by Nfrac, a resource mapping for the first signal that is input to the IFFT, where Nfrac is an integer satisfying f0−fbase=Nfrac*Δf.
In each aspect at the transmitting side, the digital module may comprise a digital oscillator. Performing the frequency up-shift of the first signal by the difference between f0 and fbase may be performed by the digital oscillator.
In each aspect at the transmitting side, the digital oscillator may reset, before transmitting the OFDM symbol signal, a phase of the OFDM symbol signal to a predetermined value at an end of a cyclic prefix of the OFDM symbol signal.
In each aspect at the receiving side, the digital module may be configured to implement a fast Fourier transformer (FFT) on the down-converted OFDM symbol signal.
In each aspect at the receiving side, performing the frequency down-shift of the down-converted OFDM symbol signal by the difference between f0 and fbase may comprise: down-shifting, by Nfrac, a resource de-mapping from the FFT for the down-converted OFDM symbol signal, where Nfrac is an integer satisfying f0−fbase=Nfrac*Δf.
In each aspect at the receiving side, the digital module may comprise a digital oscillator. Performing the frequency down-shift of the down-converted OFDM symbol signal by the difference between f0 and fbase may be performed by the digital oscillator.
In each aspect at the receiving side, the digital oscillator may reset a phase of the down-converted OFDM symbol signal to a predetermined value at an end of a cyclic prefix of the down-converted OFDM symbol signal.
The above technical solutions are merely some parts of the implementations of the present disclosure and various implementations into which the technical features of the present disclosure are incorporated can be derived and understood by persons skilled in the art from the following detailed description of the present disclosure.
According to the present invention, phase change according to symbols which occurs due to mismatch between the upconversion frequency and the downconversion frequency may be easily minimized. Accordingly, even if the upconversion frequency is unknown to the transmitting device and the receiving device, or mismatch between the upconversion/downconversion frequency and the center of the RF filter or mismatch between the carrier frequency and the center frequency of a cell occurs, the signal recovery performance at the receiving device may be maintained.
In addition, when the carrier frequency changes in the same frequency band, the carrier frequency may be easily adjusted without RF retuning.
Wireless communication systems typically communicate using specific ranges of radio frequencies (RF). To ensure proper transmission in these RF ranges, wireless systems typically implement, at the transmitter, a technique called upconversion to convert signals from a lower frequency range to a higher (RF) frequency range, and also implement, at the receiver, a technique called downconversion to convert signals from a higher (RF) frequency range to a lower frequency range.
However, difficulties may arise where information about frequency conversion is unknown to a transmitting device and/or a receiving device. In such scenarios, mismatch may occur between an upconversion frequency used by the transmitting device and a downconversion frequency used by the receiving device. Such mismatch between upconversion and downconversion frequencies may cause a phase offset in each time symbol received at the receiving device. Phase offset may degrade performance of signal recovery by channel estimation in the receiving device.
Furthermore, in some scenarios, mismatches may occur between a carrier frequency and a center frequency of a frequency band, or between the carrier frequency and a center of an RF filter. Such mismatches may also result in phase offsets in the received time symbols, which may degrade reception performance.
Therefore, difficulties may arise in systems where such phase offset occurs due to mismatch between upconversion and downconversion frequencies, or due to mismatch between the carrier frequency and the center frequency of the frequency band, or due to mismatch between the carrier frequency and the center of the RF filter. In addition, when the carrier frequency changes in the same frequency band, difficulties may arise in adjusting the carrier frequency without performing RF retuning.
Implementations disclosed herein enable a transmitter that is configured to perform upconversion in a manner that mitigates or removes such phase offset. In some implementations, the transmitter upconverts from baseband to one of a finite number of frequencies that are predetermined, and thus configured to result in no phase offset at the receiver. Since these finite number of frequencies may be different from the actual carrier frequency utilized by the transmitter, the transmitter may compensate for any such difference by pre-shifting the baseband signal by that difference.
In some implementations, the pre-shifting may be implemented either by performing frequency domain shifting (e.g., shifting an input of an inverse Fast Fourier Transform (IFFT) at the transmitter) or may be implemented by time-domain shifting (e.g., shifting an output of the IFFT, for example, using a digital oscillator).
Analogously, in some implementations, a receiver is configured to perform downconversion from one of the finite number of predetermined frequencies down to baseband. Again, since the finite number of frequencies may be different from the actual carrier frequency utilized by the receiver, the receiver may compensate for any such difference by post-shifting the resulting baseband signal by that difference.
Accordingly, implementations disclosed herein may mitigate or remove phase offsets that occur due to mismatch between the upconversion frequency and the downconversion frequency. Thus, even if the upconversion frequency is unknown to the transmitting device and the receiving device, or even if mismatch between the upconversion/downconversion frequency and the center of the RF filter occurs, or even if mismatch between the carrier frequency and the center frequency of a cell occurs, the signal recovery performance at the receiving device may be maintained.
In addition, in some scenarios, when the carrier frequency changes in the same frequency band, the carrier frequency may be easily adjusted without RF retuning.
Reference will now be made in detail to various implementations of the present disclosure, examples of which are illustrated in the accompanying drawings. The detailed description, which will be given below with reference to the accompanying drawings, is intended to explain exemplary implementations of the present disclosure, rather than to show the only implementations that can be implemented according to the disclosure. The following detailed description includes specific details in order to provide a thorough understanding of the present disclosure. However, it will be apparent to those skilled in the art that the present disclosure may be practiced without such specific details.
In some instances, known structures and devices are omitted or are shown in block diagram form, focusing on important features of the structures and devices, so as not to obscure the concept of the present disclosure. The same reference numbers will be used throughout this specification to refer to the same or like parts.
The following techniques, apparatuses, and systems may be applied to a variety of wireless multiple access systems. Examples of the multiple access systems include a code division multiple access (CDMA) system, a frequency division multiple access (FDMA) system, a time division multiple access (TDMA) system, an orthogonal frequency division multiple access (OFDMA) system, a single carrier frequency division multiple access (SC-FDMA) system, and a multicarrier frequency division multiple access (MC-FDMA) system. CDMA may be embodied through radio technology such as universal terrestrial radio access (UTRA) or CDMA2000. TDMA may be embodied through radio technology such as global system for mobile communications (GSM), general packet radio service (GPRS), or enhanced data rates for GSM evolution (EDGE). OFDMA may be embodied through radio technology such as institute of electrical and electronics engineers (IEEE) 802.11 (Wi-Fi), IEEE 802.16 (WiMAX), IEEE 802.20, or evolved UTRA (E-UTRA). UTRA is a part of a universal mobile telecommunications system (UMTS). 3rd generation partnership project (3GPP) long term evolution (LTE) is a part of evolved UMTS (E-UMTS) using E-UTRA. 3GPP LTE employs OFDMA in DL and SC-FDMA in UL. LTE-advanced (LTE-A) is an evolved version of 3GPP LTE. For convenience of description, implementations of the present disclosure are described herein as being applied to the 3GPP based communication system, especially, the NR system. However, the technical features of the present disclosure are not limited thereto. Although the following detailed description is based on a mobile communication system corresponding to the 3GPP NR system, it is applicable to any other mobile communication systems except unique features of 3GPP NR. For example, the present disclosure is applicable to a communication technology in which the upconversion frequency and the downconversion frequency are not shared in advance between the transmitting device and the receiving device and communication technologies in which mismatch may occur between the upconversion frequency and the center of the RF filter or between the upconversion/downconversion frequency and the center frequency of a cell.
In the present disclosure, a user equipment (UE) may be a fixed or mobile device. Examples of a UE include various devices that transmit and receive user data and/or various kinds of control information to and from a base station (BS). The UE may be referred to as a terminal equipment (TE), a mobile station (MS), a mobile terminal (MT), a user terminal (UT), a subscriber station (SS), a wireless device, a personal digital assistant (PDA), a wireless modem, a handheld device, etc. In addition, in the present disclosure, a base station (BS) generally refers to a fixed station that performs communication with a UE and/or with another BS, and exchanges various kinds of data and control information with the UE and/or another BS. The BS may be referred to as an advanced base station (ABS), a node-B (NB), an evolved node-B (eNB), a base transceiver system (BTS), an access point (AP), a processing server (PS), etc. In particular, the base station of the UTRAN is referred to as Node-B, the base station of E-UTRAN is referred to as eNB, and the base station of the new radio access technology network is referred to as gNB.
In the present disclosure, a node refers to a fixed point configured to transmit/receive a radio signal through communication with a UE. Various types of eNBs may be used as nodes irrespective of the terms thereof. For example, a BS, a node B (NB), an e-node B (eNB), a pico-cell eNB (PeNB), a home eNB (HeNB), a relay, a repeater, etc. may be a node. In addition, the node may not be a BS. For example, the node may be a radio remote head (RRH) or a radio remote unit (RRU). The RRH or RRU generally has a lower power level than a power level of a BS. Since the RRH or RRU (hereinafter, RRH/RRU) is generally connected to the BS through a dedicated line such as an optical cable, cooperative communication between RRH/RRU and the BS can be smoothly performed in comparison with cooperative communication between BSs connected by a radio line. At least one antenna may be installed per node. The antenna may be a physical antenna or an antenna port or a virtual antenna.
In the present disclosure, a cell may refer to a prescribed geographical area to which one or more nodes provide a communication service. Accordingly, in the present disclosure, communicating with a specific cell may include communicating with a BS or a node which provides a communication service to the specific cell. In addition, a DL/UL signal of a specific cell refers to a DL/UL signal from/to a BS or a node which provides a communication service to the specific cell. A node providing UL/DL communication services to a UE is called a serving node and a cell to which UL/DL communication services are provided by the serving node is especially called a serving cell.
A 3GPP-based communication system typically implements a cell in order to manage radio resources, and a cell associated with the radio resources is distinguished from a cell of a geographic region. For example, a “cell” of a geographic region may be understood as a coverage within which a node can provide service using a carrier, and a “cell” of a radio resource is associated with bandwidth (BW) which is a frequency range configured by the carrier. Since DL coverage, which is a range within which the node is capable of transmitting a valid signal, and UL coverage, which is a range within which the node is capable of receiving the valid signal from the UE, depends upon a carrier carrying the signal, the coverage of the node may be associated with coverage of the “cell” of a radio resource used by the node. Accordingly, the term “cell” may be used to indicate service coverage of the node sometimes, a radio resource at other times, or a range that a signal using a radio resource can reach with valid strength at other times. The “cell” associated with the radio resources is defined by combination of downlink resources and uplink resources, that is, combination of DL component carrier (CC) and UL CC. The cell may be configured by downlink resources only, or may be configured by downlink resources and uplink resources.
For terms and technologies not specifically described among the terms and technologies used in this specification, 3GPP LTE/LTE-A standard documents such as 3GPP TS 36.211, 3GPP TS 36.212, 3GPP TS 36.213, 3GPP TS 36.321 and 3GPP TS 36.331 and 3GPP NR standard documents such as 3GPP TS 38.211, 3GPP TS 38.212, 3GPP 38.213, 3GPP 38.214, 3GPP 38.215, 3GPP TS 38.321, 3GPP TS 38.300 and 3GPP TS 38.331 can be referenced.
Referring to the standard 3GPP TS 36.211, for all physical signals and physical channels except the physical random access channel, OFDM symbol baseband signals, e.g., single carrier frequency division multiple access (SC-FDMA) baseband signals, are generated as follows. In the LTE system, the time-continuous signal sl(t) in SC-FDMA symbol l in an uplink slot is defined for the time interval 0≥t<(NCP,l+N)×Ts (where the fast Fourier transform (FFT) size N is equal to 2048) by the following equation.
where k(−)=k+└NRBULNscRB/2┘, the subcarrier spacing is Δf=151 kHz, and αk,l is the content of resource element (k,l). The index k is an index numbered from 0 to NULRB×NRBsc−1 in the frequency domain, and l is an index numbered from 0 to NULsymb−1 in the time domain.
In an LTE system, the uplink transmitted signal in each slot utilizes a resource grid of NULRB×NRBsc subcarriers and NULsymb OFDM symbols. Each resource element in the resource grid is uniquely defined by the index pair (k,l) in a slot, where k=0, . . . , NULRB×NRBsc−1 and l=0, . . . , NULsynb−1. The expression NULRB denotes the number of resource blocks (RB s) in an uplink (UL) slot and depends on the uplink transmission bandwidth configured in a cell. The expression NRBsc denotes the number of subcarriers constituting one RB. In the LTE system, NRBsc=12. The RB is defined as 12 consecutive subcarriers in the frequency domain. The expression Ts is a basic time unit for LTE, wherein Ts=1/(15*103*2048) seconds. For reference, the sampling time is defined as 1/(NFFT*Δf), where NFFT is the FFT size (equal to the IFFT size) and Δf is the subcarrier spacing. When NFFT=2048 and the basic subcarrier spacing is Δf=15 kHz, the basic time unit Ts of the LTE system corresponds to the sampling time. The expression NULsymb denotes the number of SC-FDMA symbols in the UL slot, wherein NULsymb=7 for the normal cyclic prefix (CP) and NULsymb=6 for the extended CP. The expression NCP,l is the cyclic prefix length. The following table lists the values of NCP,l used on an uplink of the LTE system.
The SC-FDMA symbols in a slot are transmitted in increasing order of l, starting with l=0, where SC-FDMA symbol l>0 starts at a time, within the slot, given by the expression
The time-continuous signal sl(p)(t) on antenna port p in orthogonal frequency division multiplexing (OFDM) symbol l in a downlink slot is defined for 0≤l<(NCP,l+N)×Ts by the following equation.
where k(−)=k+└NRBDLNscRB/2┘, and k(+)=k+└NRBDLNscRB/2┘−1. In the time interval 0≥l<(NCP,l+N)×Ts, the variable N equals 2048 for subcarrier spacing Δf=15 kHz and equals 4096 for subcarrier spacing Δf=7.5 kHz. The OFDM symbols in a slot are transmitted in increasing order of l, starting with l=0, where OFDM symbol 1>0 starts at time
within the slot. The index k is an index numbered from 0 to NDLRBxNRBsc-1 in the frequency domain, and 1 is an index assigned values from 0 to NDLsymb-1 in the time domain.
In the LTE system, the downlink transmitted signal in each slot is described by a resource grid of NDLRB×NRBsc subcarriers and NDLsymb OFDM symbols. Each resource element in the resource grind is uniquely identified by the index pair (k,l) in a slot, where k=0, . . . , NDLRB×NRBsc−1 and/=0, . . . , NULsymb-1. NDLRB denotes the number of RBs in a DL slot and depends on the downlink transmission bandwidth configured in a cell. NDLsymb denotes the number of OFDM symbols in the DL slot, wherein NDLsymb=7 for the normal cyclic prefix (CP) and NDLsymb=6 for the extended CP. NCP,l is the cyclic prefix length. The following table lists the values of NCP,l used on downlink in the LTE system.
Filtering may be performed prior to uplink transmission, for example as specified by the standard 3GPP TS 36.101, and likewise filtering may be performed prior to downlink transmission, for example as specified by the standard 3GPP TS 36.104. In the examples of
In some systems (e.g., in an LTE system), since a synchronization signal of the cell and a physical broadcast channel (PBCH) of the cell are transmitted in a total of six RBs around the carrier frequency of the cell, the user equipment (UE) of the LTE system can know the downlink carrier frequency of the cell by acquiring the synchronization signal and the PBCH. In such scenarios, if the UE and the base station (BS) know the downlink carrier frequency, then they may also know the uplink carrier frequency in scenarios where (i) the downlink carrier frequency and the uplink carrier frequency are the same, for example, in the case of time division duplex (TDD), or where (ii) the uplink carrier frequency used together with the downlink carrier frequency is predetermined, for example, in the case of frequency division duplex (FDD), or where (iii) the uplink carrier frequency is explicitly broadcast through the system information of the cell or the like. As a result, in such scenarios of the LTE system, both the UE and the base station (BS) may know the carrier frequency of a cell used for transmission/reception of a radio signal.
In a legacy LTE system, the following frequencies are configured to be the same: (i) the center of a radio frequency (RF) filter (e.g., a filter between IFFT and upconversion, a filter applied after upconversion, etc.), (ii) the center frequency of the carrier bandwidth, and (iii) the upconversion frequency f0. In addition, the same frequency is used for up-converting the baseband to the carrier frequency signal and for down-converting a radio signal to the baseband signal.
However, with the increase in various utilizations of Machine Type Communication (MTC), Internet of things (IoT) communications, and ultra-reliable and low latency communication (URLLC), a new radio access technology (NR) different from the legacy LTE communication technology is under development. The NR system considers use of frequencies above the frequency band used in the legacy communication system and also considers supporting a bandwidth much wider than the frequency bandwidth used in the legacy communication system. Considering the drawbacks of the legacy LTE system, in which it is difficult to introduce a communication technology having forward compatibility due to various constraints, the NR system is being developed so as to reduce such constraints and thereby facilitate introduction of future communication technology having forward compatibility with the NR system.
Accordingly, in the NR system, the frequency used for upconversion of the baseband signal is not necessarily limited to the center frequency of the cell. In addition, in the NR system, the frequency resource through which the synchronization signal is transmitted is not necessarily limited to be the center of the frequency band of the cell.
Considering that the UE may not be able to support a wide bandwidth to be supported in the NR system at one time, the UE may be configured to operate in a part of the frequency bandwidth (hereinafter, bandwidth part (BWP)) of the cell. The BWP may be assigned based on any reference point. The reference point is not necessarily limited to be the center frequency of the cell. If only a part of the frequency bandwidth of the cell is used for communication such as BWP-based communication and NB-IoT, the receiving device may not know the upconversion frequency used by the transmitting device before downconversion of the receiving signal.
Accordingly, the upconversion frequency for the baseband signal may be different from the downconversion frequency for the radio signal, and the upconversion frequency is not necessarily limited to be the center of the RF filter.
In addition, it is expected that a variety of numerologies will be supported in the NR system. If the numerology for the same frequency band changes, the subcarrier spacing may change. This change in subcarrier spacing may result in change in the upconversion frequency or the downconversion frequency. Therefore, there is a need for a technique by which the transmitting device and the receiving device can easily adjust the upconversion frequency and the downconversion frequency, respectively.
Before explaining implementations of the present disclosure in further detail, the basic frame structure and physical resources of the NR system so far discussed will be described in order to facilitate understanding of the present disclosure.
In the description of the present disclosure, unless otherwise noted, the size of various fields in the time domain is expressed in time units Tc=1/(Δfmax*Nf), where Δfmax=480*103 Hz and Nf=4096, or in time units Ts. Tc is the basic time unit for NR. The constant K=Ts/Tc=64, where Ts=1/(Δfref*Nf,ref), Δfref=15*103 Hz, Nf,ref=2048. Ts is the basic time unit for LTE. In NR, multiple OFDM numerologies are supported as given by the following table, where μ and the cyclic prefix for a bandwidth part are given by the higher-layer parameters provided by a BS.
Downlink and uplink transmissions are organized into frames with Tf=(ΔfmaxNf/100)*Tc=1 Oms duration, each consisting of Tsf=(ΔfmaxNf/1000)*Tc=1 ms duration. The number of consecutive OFDM s subframe Nsymbsubframe,μ=NsymbslotNslotsubframe,μ. Each frame is divided into two equally-sized half-frames of five subframes. There is one set of frames in the uplink and one set of frames in the downlink on a carrier.
For subcarrier spacing configuration μ, slots are numbered nsμ∈{0, . . . , Nslotsubframe,μ−1} in increasing order within a subframe. There are Nsymbslot consecutive OFDM symbols in a slot where Nsymbslot depends on the cyclic prefix as given by Table 4 and Table 5. Table 4 shows the number of OFDM symbols per slot, the number of slots per frame, and the number of slots per subframe, for the normal cyclic prefix, and Table 5 shows the number of OFDM symbols per slot, the number of slots per frame, and the number of slots per subframe, for the extended cyclic prefix.
In Table 4 and Table 5, Nsymbslot denotes the number of symbols per slot, Nslotframe,μ is the number of slots per frame for subcarrier configuration μ, Nslotsubframe,μ is the number of slots per subframe for subcarrier configuration μ.
For each numerology and carrier, a resource grid of Ngrid,xsize,μNscRB subcarriers and Nsymbsubframe,μ OFDM symbols is defined, starting a common resource block Ngridstart,μ indicated by higher-layer signaling by a BS, where Ngrid,xsize,μ is the size of the resource grid and NscRB is the number of subcarriers per resource block. There is one set of resource grids per transmission direction (DL or UL) with the subscript x set to DL and UL. The subscript x is DL for downlink and UL for uplink. When there is no risk for confusion, the subscript x may be dropped. There is one resource grid for a given antenna port p, subcarrier spacing configuration μ, and transmission direction (downlink or uplink). Each element in the resource grid for antenna port p and subcarrier spacing configuration μ is called a resource element and is uniquely identified by (k,l)p,μ where k is the index in the frequency domain and l refers to the symbol position in the time domain relative to some reference point. Resource element (k,l)p,μ corresponds to the complex value ak,l(p,μ). When there is no risk for confusion, or no particular antenna port or subcarrier spacing is specified, the indices p and μ may be dropped, resulting in ak,l(p) or ak,l.
A resource block (RB) is defined as NRBsc=12 consecutive subcarriers in the frequency domain. Reference resource blocks are numbered from 0 and upward in the frequency domain. Subcarrier 0 of reference resource block 0 is common for all subcarrier spacing configurations μ, also denoted as ‘reference point A’ or ‘point A’, and serves as a common reference point for other resource block grids. Reference point A is obtained from the higher-layer parameter provided by a BS. Common resource blocks (CRBs) are numbered from 0 and upwards in the frequency domain for subcarrier spacing configuration μ. Subcarrier 0 of common resource block 0 for subcarrier spacing configuration μ coincides with the reference point A. The relation between the common resource block number nCRB in the frequency domain and resource elements (k,l) for subcarrier spacing configuration μ is given by the following equation.
where k is defined relative to subcarrier 0 of the resource grid for subcarrier spacing configuration μ.
In the NR system, physical resource blocks (PRBs) are defined within a carrier bandwidth part and numbered from 0 to NBWP,isize−1, where i is the number of the carrier bandwidth part and NBWP,isize is the size of bandwidth part i. The relation between physical and common resource blocks in carrier bandwidth part i is given by the following equation.
nCRB=nPRB+NBWP,istart Equation 4
where NBWP,istart is the common resource block where the carrier bandwidth part starts relative to common resource block 0.
A bandwidth part is a subset of contiguous common resource blocks defined for a given numerology μi in the bandwidth part i on a given carrier. The starting position NBWP,istart,μ and the number of resource blocks NBWP,isize,μ in a bandwidth part shall fulfill Ngrid,xstart,μ≤NBWP,istart,μ<Ngrid,xstart,μ+Ngrid,xsize,μ and Ngrid,xstart,μ<NBWP,isize,μ+NBWP,istart,μ≤Ngrid,xstart,μ+Ngrid,xsize,μ. A UE can be configured with the certain number (e.g. up to four) of bandwidth parts in the downlink with a single downlink bandwidth part being active at a given time. A UE can be configured with the certain number (e.g. up to four) of bandwidth parts in the uplink with a single uplink bandwidth part being active at a given time.
In some wireless communication systems, the carrier frequency used by the transmitter and the receiver are known to each other, and the transmitter and the receiver set the same carrier frequency as the upconversion frequency and the downconversion frequency, respectively. However, due to inaccuracy of the analog oscillator or the phase-locked loop (PLL), an error, i.e., a frequency offset, occurs between the frequencies generated by the transmitter and the receiver. In this case, the signal phase varies depending on the symbols at the receiving end. However, generally, phase change due to inaccuracy of the analog module is not so serious as to make channel estimation with the reference signal (RS) useless and, generally, such phase change does not greatly affect the received signal recovery.
On the other hand, in a radio communication system such as an NR system supporting a wideband cell, the UE and the BS may have to operate without the information on a carrier frequency for upconversion known to the UE and the BS. Therefore, when the UE and the BS perform upconversion and downconversion using different carrier frequencies, the phase of the receiving device may change abruptly in each symbol as will be described later even if it is assumed that there is no frequency offset, i.e., frequency error, resulting from the inaccuracy of the analog oscillator or the PLL.
The time-continuous signal sl(p,μ)(t) on antenna port p and subcarrier spacing configuration μ for OFDM symbol l in a subframe for any physical channel or signal except the physical random access channel (PRACH) is defined by the following equation.
where 0≤t<Nuμ+NCP,lμ)Tc. Equation 5 may be expressed as:
where tstart,lμ≤t<tstart,lμ+(Nuμ+NCP,lμ)Tc is the time within the subframe.
In Equation 5 and Equation 6, the value of k0μ is obtained from the higher-layer parameter k0 provide by a BS, and is such that the lowest numbered subcarrier in a common resource block for subcarrier spacing configuration μ coincides with the lowest numbered subcarrier in a common resource block for any subcarrier spacing configuration less than μ. The starting position tstart,lμ of OFDM symbol l for subcarrier spacing configuration μ in a subframe is given as follows.
Here, the effective symbol length Nμu of OFDM symbol l and the cyclic prefix (CP) length NμCP,l of OFDM symbol l are given as:
The time continuous signal sl(p,μ)(t) on antenna port p for PRACH is defined by the following equation.
where 0≤t<(Nu+NCP,lRA)Tc. A detailed description of each parameter in Equation 9 can be found in 3GPP TS 38.211.
The transmitting device up-converts the OFDM symbol baseband signal sl(p,μ)(t) for the antenna port p and the subcarrier spacing configuration μ to the uplink frequency fTx using the free-running oscillator of the frequency fTx. The upconversion of the OFDM symbol baseband signal sl(p,μ)(t) for the antenna port p and the subcarrier spacing configuration μ to the upconversion frequency fTx may be expressed as:
In Equation 10, NRBμ may be the number of RBs for the subcarrier spacing configuration μ. NRBμ may be Ngrid,xsize,μ, Ngrid,xsize,μ is a value configured by the BS, and the UE may know Ngrid,xsize,μ through the system information. Since a signal that is actually transmitted in a final signal that the transmitting device obtains by multiplying a transmitted signal by ej2πf
x(p,μ)(t)=Re{sl(p,μ)(t)·ej2πf
Even if the transmitting device transmits only the real value of the complex signal, the receiving device applies FFT after converting the received signal back into the complex signal. Therefore, in the description of the present disclosure, the transmitted signal is expressed as a complex signal for convenience, and is equivalent to the real signal in modeling. The same applies to the reception operation.
When a radio signal x(p,μ)(t) is received by the receiving device, the receiving device performs frequency downconversion on x(p,μ)(t) to obtain the baseband signal {circumflex over (x)}(p,μ)(t). When it is assumed that the receiving device uses an arbitrary frequency fRx in frequency downconversion, the frequency downconversion of the radio signal x(p,μ)(t) for the antenna port p and the subcarrier spacing configuration μ may be expressed as:
To show the phase change of the received signal {circumflex over (x)}(p,μ)(t), the frequencies fTx and fRx may be expressed as fTx=NTx*Δf+Δoffset and fRx=NRx*Δf+Δoffset where the term Δf is the subcarrier spacing, the term NTx is a positive integer closest to fTx/Δf (e.g., floor{fTx/Δf} or ceil{fTx/Δf}), the term NRx is a positive integer closest to fRx/Δf (e.g., floor{fRx/Δf} or ceil{fRx/Δf}), and the term Δoffset is a real number whose magnitude is smaller than Δf. In the description of the present disclosure, fTx and fRx are expressed using the same Δoffset for simplicity, but Δoffset may differ between fTx and fRx.
Using these expressions, Equation 12 may be rearranged as given below.
Even in an environment in which there is no frequency offset, which is a frequency error unintentionally produced by the characteristics of the transmitter/receiver components, the received signal {circumflex over (x)}(p,μ)(t) may suffer phase change by Ψl=2πΔf (NTx−NRx) (tstart,l+NCP,lμTc) in frequency upconversion or frequency downconversion if fTx is not equal to fRx for the following reason. In Equation 5, if expressing t−NCP,lμTc as t′, t−NCP,lμTc in sl(p, μ)(t), i.e., time t′ at which inverse fast Fourier transform (IFFT) is applied is defined only for TCP≤t<TOFDM (i.e., −NCP,lμTc≤t′<NuμTc), but t in ej2πf
Referring to
Referring to
Therefore, if fTx is not equal to fRx, performance is significantly degraded in the signal recovery process through channel estimation at the receiving end due to the abrupt phase change between the symbols caused by the difference between fTx and fRx. If the phase is abruptly changed between the OFDM symbols, the receiver cannot apply a channel estimation value obtained using the reference signal (RS) of a specific OFDM symbol to other OFDM symbols, or the received signal may not be restored properly when the channel estimation value is used. It is not appropriate for the transmitter to insert an RS in every OFDM symbol to allow the receiver to correctly estimate the channel state of each symbol because the RS overhead becomes excessively large.
Several types of techniques may be utilized for an NR system to mitigate such issues of phase discontinuity/mismatch between symbols. Some examples of such techniques are described below, along with potential disadvantages of each.
Technique A: The gNB Informs the UE of the Carrier Frequency that the gNB Uses, and the UE Compensates for the Corresponding Phase Discontinuity.
According to this scheme, if the BS transmits a transmitted signal without separately performing pre-compensation thereon, the UE performs compensation for phase discontinuity for each symbol using the carrier frequency information of the BS. For example, the UE, which is the receiver, performs phase compensation so as to cancel the phase discontinuity occurring due to ej2π(f
Technique B: The BS, which is a Transmitter, Performs Phase Pre-Compensation Using the DL Carrier Frequency Information of the UE.
This technique may be implemented, for example, in the NB-IOT system as an operation before the receiver receives the information about the carrier frequency in Implementation A. For example, the transmitter performs phase pre-compensation to cancel the phase discontinuity occurring due to ej2π(f
Technique C: The Transmitter and the Receiver Perform Phase Pre-Compensation Assuming a Common Reference Point.
In this technique, the transmitter does not use the information about the carrier frequency of the receiver (and the receiver does not use the information about the carrier frequency of the transmitter). Instead, a common reference point is predefined between the transmitter and the receiver and phase pre-compensation for the reference point is performed on a symbol-by-symbol basis. For example, the transmitter performs phase (pre-)compensation on the phase discontinuity occurring due to ej2π(f
Here, Δfref=15 kHz, and λlμ=e−j2π·(p
Here M={−1, 0, 1} for bands between 0 to 2.65 GHz and M=0 for the other bands. Δ, the phase compensation value, is determined between the quantized carrier frequency and the non-quantized carrier frequency, where Δ=0 for the quantized carrier frequency, Δ=f0−pμΔfref for the non-quantized carrier frequency. Here f0 is the carrier frequency of the receiver and k is a variable. Therefore, k that minimizes the absolute value of ‘f0−M*5 kHz−kΔfref’ may be pμ. This technique, however, is disadvantageous in that phase compensation is always performed by both the transmitter and the receiver. In addition, according to this technique, the transmitter and the receiver calculate the phase for each symbol based on the carrier frequency thereof and apply the compensation term to the signal. Therefore, assuming that all available frequencies, that is, all frequencies to which subcarriers can be mapped, can become carrier frequencies, the phase compensation term becomes a function of a very high resolution and a very long periodicity, requiring a very complex implementation.
For reference, the NR standard does not explicitly specify a particular technique for implementation. In the NR standard, a modulation and upconversion technique is defined as shown in the following table below such that the transmitting side and the receiving side respectively reset the carrier frequency to zero phase on the symbol-by-symbol basis to maintain a certain value of the phase of the carrier frequency at the starting point of each symbol (see 3GPP TS 38.211 section 5.4). This is specified in the standard document 3GPP TS 38.211 V15.1.0 as follows.
When Equation 15 is rearranged to explain how Equation 15 appears in an actual implementation, the follow equation is obtained.
Techniques for adding phase discontinuity/mismatch described thus far define a phase reset at the carrier frequency level. For actual upconversion (or downconversion) of the carrier frequency level, components such as a phase-locked loop (PLL) and a mixer are used.
Referring to
In other words, referring to Table 6, the NR standard specifies that a phase reset should be implemented by directly controlling the phase of the carrier frequency. However, in some scenarios, it may be difficult in reality to directly control the phase of the carrier frequency. Therefore, due to this practical difficulty of directly controlling the phase at the carrier frequency, some systems perform upconversion and downconversion using a carrier frequency having a continuous phase at the carrier frequency level, and further implement, at the baseband level, a phase reset function for eliminating the resulting phase discontinuity/mismatch between the symbols caused by upconversion/downcoversion at the analog level.
In such systems, referring to Equation 16, upconversion and downconversion at the carrier frequency level using a carrier frequency having a continuous phase corresponds to ej2πf
Therefore, in such systems, the transmitting side and the receiving side compensate the phase using only their respective carrier frequencies, which correspond to ψTx,l=−2πfTx(tstart,l+NCP,lμTc) and ψRx,l=2πfRx(tstart,l+NCP,lμTc) in Equation 16, respectively. This corresponds to the transmitting side performing phase compensation assuming that the receiver uses the direct current (DC) tone, i.e., 0, as the carrier frequency for downconversion, and the receiving side performing phase compensation assuming that the transmitter uses the DC tone as the carrier frequency for upconversion. In such scenarios, if the transmitting side and the receiving side operate without information about the carrier frequency, then the term ej2πf
Therefore, the current NR standard (3GPP TS 38.211 V15.1.0) may be understood as specifying that the transmitting side utilizes ej2πf
As discussed above (regarding Techniques A to C), some wireless communication systems that are based on the NR standard may apply a phase compensation term by calculating the phase in every symbol based on the carrier frequency. However, considering the myriad applicable or available frequencies as fXX (where XX is TX or RX), this phase compensation term may become a function of a very high resolution and a very long periodicity, potentially imposing a very complex implementation.
To address such challenges, the present disclosure describes implementations for addressing scenarios where the transmitter and the receiver operate without knowing the carrier frequency used for transmission or without knowledge of the upconversion/downconversion frequency.
Techniques for Lowering Complexity
The current NR standard defines the following numerologies (see, e.g., section 5.4 of 3GPP TS 38.101-1 and section 5.4 of 3GPP TS 38.101-2).
The NR standard has two major frequency ranges (FR) specified in 3GPP. One is commonly referred to as sub-6 GHz and corresponds to frequency range FR1 in Tables 7 and 8 and the other is referred to as millimeter wave and corresponds to frequency range FR2 in Tables 7 and 8. Depending on the frequency range, the maximum bandwidth and the available subcarrier spacing(s) differ.
Table 7 shows the channel raster, i.e., the NR-ARFCH definition, and Table 8 shows the synchronization raster.
The channel raster defines a set of RF reference frequencies that are used to identify radio frequency (RF) channel positions. The RF reference frequencies for RF channels are mapped to resource elements on the carrier. A global frequency raster is defined for all frequencies from 0 to 100 GHz and is used to define a set of allowed RF reference frequencies. The granularity of the global frequency raster is ΔFGlobal. For each operating band, a subset of frequencies from the global frequency raster is applicable to that band and forms a channel raster for that band with the granularity ΔFGlobal.
The synchronization raster represents the frequency position of a synchronization (SS) block that can be used by the UE for system acquisition when there is no explicit signaling about the SS block position. A global synchronization raster is defined for all frequencies and the frequency position of the SS block is defined as SSREF with the corresponding global synchronization channel number (GSCN).
Mapping between the synchronization raster and the corresponding resource elements of the SS block is given in Table 8. The mapping depends on the total number of RBs allocated in the channel and is applied to both UL and DL. Table 8 shows the position of resource element (RE) #0 (i.e., subcarrier #0) of RB #10 of the SS block. The SS block is composed of twenty RBs. When twenty RBs constituting the SS block are indexed from 0 to 19, the frequency indicated by the synchronization raster corresponds to the first RE, i.e., the position of the first subcarrier of RB #10 among RB #0 to RB #19.
The channel raster and the SS raster are fixed to certain values as shown in Tables 7 and 8. Therefore, if the carrier frequency is expressed as fTx=NTx*Δf+Δoffset, then the offset term Δoffset may be limited to some specific values (e.g., −5 kHz, 0 or 5 kHz) for frequency range FR1 (<3 GHz) and be 0 for the remaining frequency bands. In the above expression, as discussed in regards to Equation 12, the term Δf is the subcarrier spacing, the term NTx is a positive integer closest to fTx/Δf (e.g., floor{fTx/Δf} or ceil{fTx/Δf}), and the term Δoffset is a real number whose magnitude is smaller than Δf (hereinafter, descriptions that are applied to fTx are also applicable to fRx).
In addition, the numbers of samples, including the number of samples for a cyclic prefix (CP), which are used for each symbol in the current LTE/NR communication system are integer multiples of 16 for every subcarrier spacing with respect to a sample time determined based on Δf. That is, the CP length is 144=16*9 or 160=16*10, and the length of the signal part of the OFDM symbol other than the CP part is 2048=16*128. For example, for a bandwidth of 20 MHz, which is the Δf=15 kHz subcarrier spacing in the LTE or NR standard, the sampling frequency is 30.72 MHz, one subframe (or one slot) is composed of 30720 samples, and each OFDM symbol is composed of 2048+144 sample times or 2048+160 sample times. For reference, in the description of the present disclosure, each sample time Ts is 1/(30.72 MHz), i.e., Ts=1/(2048*15*103 kHz).
In some scenarios, NR and LTE systems may use values that are proportional to the numerology corresponding to the bandwidth of 20 MHz, which is a Δf=15 kHz subcarrier spacing, as numerologies, and therefore it should be noted that all frequencies described in the present disclosure are based on the numerology corresponding to the bandwidth of 20 MHz, which is a 15 kHz subcarrier spacing. Here, 2048 is the signal length (i.e., the effective symbol length of the OFDM symbol) defined by the FFT size when the numerology above (e.g., the 15 kHz subcarrier spacing and the 20 MHz bandwidth) is used, 144 and 160 correspond to cyclic prefix (CP) lengths when the numerology above (e.g., the Δf=15 kHz subcarrier spacing and the 20 MHz bandwidth) is used.
The phase reset for the transmitted signal and the received signal may be implemented, for example, to address scenarios where the signal periodicity according to the upconversion frequency is not an integer multiple of the OFDM symbol length, where the OFDM symbol length is equal to the length of the cyclic prefix (CP) part plus the length of the signal part. Therefore, in some scenarios, if a carrier frequency according to which an integer multiple of the signal periodicity has a periodicity corresponding to the OFDM symbol length is used, then phase reset may not be implemented.
For example, consider a communication system in which the cyclic prefix (CP) part of an OFDM symbol consists of 144=16*9 samples or 160=16*10 samples, and the signal part of the OFDM symbol consists of 2048=16*128 samples, and the IFFT/FFT size is 2048. In such a system, no phase reset would be required if the upconversion frequency is set to a frequency with a periodicity of 16 samples, or frequency 1/(16*Ts), where 16 is the greatest common divisor of {144, 160, 2048}. Substituting for the sampling time Ts, then this corresponds to an upconversion frequency equal to 1/(16*Ts)=1/{16*1/(FFT size*Δf)}=1/{16*1/(2048*Δf)}=128Δf. As such, if the upconversion frequency is set to the value 1/(16*Ts)=128Δf, then no phase reset would be required.
The reason for this is that a frequency having a periodicity of 16 samples (16 being the greatest common divisor of 144, 160, and 2048) has the same phase at the beginning of each signal part of the OFDM symbols. In particular, this is because for a sine wave having a period of 16*Ts, nine such sine waves are included in a CP part having a length of 144 Ts, 10 such sine waves are included in a CP part having a length of 160 Ts, and 128 such sine waves are included in a CP part having a length of 2048 Ts. For example, considering the minimum subcarrier spacing Δf=15 kHz supported by the NR system, if a carrier frequency corresponding to an integer multiple of 15 kHz*2048/16=15 kHz*128=1.92 MHz is used, then the phase naturally becomes 0 at the beginning of the signal part of each OFDM symbol, and therefore problems of phase offset do not occur.
Further, according to a numerology having a subcarrier spacing of Δf=15 kHz, cyclic prefix (CP) lengths of 144 Ts and 160 Ts, and a signal part (i.e., effective symbol) length 2048 Ts of an OFDM symbol, the phase would be 0 even at the CP start point in the case of a frequency corresponding to an integer multiple of 1.92 MHz. In more general terms, when a plurality of CP lengths (e.g., NCP,1, NCP,2, . . . ) are defined for OFDM symbol signal generation and the number of effective samples per OFDM symbol, i.e., the number of samples (i.e., IFFT/FFT size) in the signal part except the CP in an OFDM symbol, is Nsample, then a frequency that does not cause phase discontinuity per symbol would be a frequency of which one period corresponds to samples the number of which corresponds to the greatest common divisor of {NCP,1, NCP,2, . . . , Nsample}.
Such a frequency that does not cause phase discontinuity per symbol may be expressed using a subcarrier spacing as follows:
Here, gcd{NCP,1, NCP,2, . . . , Nsample} is the greatest common divisor of NCP,1, NCP,2, . . . , and Nsample.
Applying this to the aforementioned numerology of 2048, 160 and 144 yields NbaseΔf=128Δf the FFT size=4096 is used, then the cyclic prefix (CP) lengths are changed to 144*2 and 160*2 in the NR standard. Thus, applying the changed CP lengths to
yields the same result of Nbase=128.
As another example, even when the FFT size is reduced from 2048 to, for example, FFT size=1024, the CP lengths are changed to 144/2=72 and 160/2=80. Therefore, applying the changed CP lengths to
yields the same result of Nbase=128.
Hereinafter, the present disclosure describes implementations of communication systems (e.g., LTE system, or an NR system) in which the length of the cyclic prefix (CP) part and the length of the signal part are 144*2μ or 160*2μ and the length of the signal part of the OFDM symbol is 2048*2μ (where μ is an integer), as an example.
In such scenarios, a frequency that does not cause phase discontinuity may be represented using 128Δf. However, implementations are not limited thereto, and the present disclosure is applicable even in scenarios where a CP length and a signal part length different from the illustrated CP length and signal part length are used.
For example, implementations of the present disclosure may be applied in scenarios where a frequency having one period corresponding to samples whose number corresponds to the greatest common divisor of {NCP,1, NCP,2, . . . Nsample} is used as a base carrier frequency fbase, that is, where an integer multiple of
is used as fbase.
As such, in the following description, the base carrier frequency fbase, which was described above as an integer multiple of 128Δf, may be generalized to an integer multiple of a frequency having one period corresponding to a number of samples which corresponds to the greatest common divisor of {NCP,1, NCP,2, . . . , Nsample}, or an integer multiple of
For the scenario of using a base carrier frequency of 128Δf, the fTx can be expressed as follows:
Here, the term └NTx/128┘int, the term Nfrac=modulo(NTx, 128), the term fbase is the quantized (down-quantized, e.g., with a floor function) version obtained with a resolution of 128Δf (e.g., 1.92 MHz resolution when Δf 15 kHz) among the carrier frequencies, and the term ffrac is a version quantized with Δf for differences between fbase and fTx.
The term Δoffset represents the offset from the frequency in units of Δf=15 kHz. In the NR system, Δoffset may be set to be +/−5, 0 kHz, for example. In particular, Δoffset may be defined to be one of −5 kHz, 5 kHz, and 0 kHz based on the Δf=15 kHz subcarrier spacing. In some implementations, Nint may be replaced by the round function instead of the floor function. In this case, Nfrac may be defined as Nfrac=NTx−128*round(NTx/128). When Nit is replaced by the round function instead of the floor function, other operations except Nfrac=NTx−128*round(NTx/128) are the same as when Nint is defined as the floor function.
In Equation 17, the base carrier frequency fbase frequency for always resetting the phase to a certain value in an OFDM symbol unit. Therefore, the expression ψTx,l=−2πfTx(tstart,l+NCP,lμTc) corresponding to phase compensation has the same value as ψTx,l=−2π(NfracΔf+Δoffset)·(tstart,l+NCP,lμTc).
Considering only the normal cyclic prefix (CP), the value of the phase compensation term ψTx,l=2π(NfracΔf+Δoffset)·(tstart,lμ+NCP,lμTc) to be applied to one symbol for the carrier frequency difference between the transmitter and the receiver is one of 128*3 complex values according to combinations of Nfrac=0, . . . , 127 and Δoffset=−5 kHz, 0 kHz, 5 kHz, and is one of 128 complex values (e.g., Nfrac=0, . . . , 127) for frequency range FR1 (>3 GHz) with Δoffset=0 or frequency range FR2. The phase compensation values to be applied to a plurality of symbols constituting a predetermined time unit (e.g., slot, subframe, 1 ms, etc.) with respect to a carrier frequency difference between the transmitter and the receiver differ among the symbols.
Therefore, if a set of phase compensation values for the plurality of symbols is expressed as a sequence, considering only the normal cyclic prefix (CP), the phase compensation term ψTx,l=−2π(NfracΔf+γoffset)·(tstart,lμ+NCP,lμTc) needs 128*3 sequences according to the combinations of Nfrac=0, . . . , 127 and Δoffset=−5 kHz, 0 kHz, 5 kHz. If the number of possible values of Δoffset is changed to b other than 3, then 128*b sequences may be needed for phase compensation. For the frequency range FR1 (>3 GHz) with Δoffset=0 or FR2, only 128 sequences (e.g., Nfrac=0, . . . , 127) may be needed. Here, the phase compensation term has a period of up to 1 ms. That is, assuming that one period of the signal part of each OFDM symbol is 2048 sample times, if the phase value for a specific carrier frequency at an arbitrary OFDM symbol boundary is ak,l, the same phase value a appears after 2048 sample times, i.e., 1 ms, since the sample time Ts=1/15000*2048 seconds. fTx=Nint*128Δf+Nfrac*Δf+Δoffset, and phase compensation is not needed for Nini*128Δf. Therefore, in the NR system, the phase compensation term ψTx,l=−2πfTx(tstart,l+NCP,lμTc) can be calculated as follows.
ψTx,l+−2π(NfracΔf+Δoffset)·(tstart,l+NCP,lμTc) Equation 18
Using the original definition of carrier frequency fTx=N′Tx*Δf+Δoffset, the final signal at the transmitting side can be given as follows.
Implementation 1
In Implementation 1, the carrier frequency fTx is used for frequency upconversion using a free-running OSC and the carrier frequency fRx is used for frequency downconversion using the free-running OSC.
Referring to
Implementation 1 is performed in an analogous way at the receiving side. An example of an operation of Implementation 1 at the receiving side is described in detail below.
In scenarios where the carrier frequency is expressed as fRx=NRx*Δf+Δoffset, then the Δoffset may be −5 kHz, 0 kHz or 5 kHz in frequency range FR1 (<3 GHz) at the receiver and is 0 kHz in the other frequency bands, as described above for the transmitter structure. In addition, the numbers of samples, including the number of samples for a cyclic prefix (CP), which are used for each symbol in the current LTE/NR communication system are integer multiples of 16 for every subcarrier spacing with respect to a sample time determined based on Δf. Therefore, in this case, when Δf=15 kHz, if a carrier frequency corresponding to an integer multiple of 15 kHz*2048/16=15 kHz*128=1.92 MHz is used for downconversion, then the phase of the signal part (i.e., valid symbol) will naturally start with 0 at every OFDM symbol, and therefore the aforementioned issue may not be raised. In addition, given a subcarrier spacing of Δf=15 kHz, CP lengths of 160 Ts and 144 Ts, and an effective symbol length of 2048 Ts, which correspond to the numerology currently available in the LTE and NR systems, the phase is 0 even at the CP start point in the case of a frequency corresponding to an integer multiple of 1.92 MHz.
More generally, when a plurality of cyclic prefix (CP) lengths (e.g., NCP,1, NCP,2, . . . ) is defined for OFDM symbol signal generation and the number of effective samples per OFDM, i.e., the number of samples (i.e., IFFT/FFT size) in the signal part except the CP in an OFDM symbol, is Nsample, then a frequency of which one period corresponds to samples the number of which corresponds to the greatest common divisor of {NCP,1, NCP,2, . . . , Nsample} is a frequency that does not cause phase discontinuity per symbol. Such a frequency that does not cause phase discontinuity per symbol may be expressed using a subcarrier spacing, as follows:
Here, gcd{NCP,l, NCP,2, . . . , Nsample} is the greatest common divisor of NCP,1, NCP,2, . . . , and Nsample.
Applying this to the aforementioned numerology (i.e., 2048, 160, 144) yields NbaseΔf=128Δf. If the FFT size=4096 is used in the example of the bandwidth of 20 MHz, which is the Δf=15 kHz subcarrier spacing, the cyclic prefix (CP) lengths are changed to 144*2 and 160*2 in the NR standard. Thus, applying the changed CP lengths to
yields the same result of Nbase=128. As another example, even when the FFT size is reduced from 2048 to, for example, FFT size=1024, the CP lengths are changed to 144/2=72 and 160/2=80. Therefore, applying the changed CP lengths to
yields the same result of Nbase=128. As mentioned above, the frequency not causing phase discontinuity will be represented using 128Δf below.
Using 128Δf, the fRx can be expressed as:
Here, N└NRx/128┘int, Nfrac=modulo(NRx,128), fbase is the quantized (down-quantized, i.e., with a floor function applied) version obtained with a resolution of 128Δf (e.g., 1.92 MHz resolution when Δf=15 kHz) among the carrier frequencies, and frac is a version quantized with Δf for differences between fbase and fRx. The Δoffset represents the amount off the frequency in units of Δf=15 kHz. In the NR system, Δoffset may be set to be +/−5, 0 kHz, for example. In particular, Δoffset may be defined to be one of −5 kHz, 5 kHz, and 0 kHz based on the Δf=15 kHz subcarrier spacing. In some implementations, the Nint may be replaced by the round function instead of the floor function. In this case, Nfrac can be defined as Nfrac=NTx−128*round(NTx/128). When Nint is implemented by the round function instead of the floor function, then other operations except Nfrac=NTx−128*round(NTx/128) are the same as when Nint is defined as the floor function.
In Equation 20, fbase is a frequency for always resetting the phase to a certain value in an OFDM symbol unit, and therefore ψRx,l=2πfRx(tstart,l+NCP,lμTc) corresponding to phase compensation has the same value as ψRx,l=2π(NfracΔf+Δoffset)·(tstart,l+NCP,lμTc). Therefore, considering only the normal cyclic prefix (CP), the phase compensation term ψRx,l=2π(NfracΔf+Δoffset)·(tstart,l+NCP,lμTc) needs only 128*3 sequences according to combinations of Nfrac=0, . . . , 127 and Δoffset=−5 kHz, 0, 5 kHz. If the number of possible values of Δoffset is changed to a value b other than 3, then 128*b sequences may be implemented for phase compensation. For frequency range FR1 (>3 GHz) with Δoffset=0 or frequency range FR2, only 128 sequences (e.g., Nfrac=0, . . . , 127) may be implemented. Here, the phase compensation term has a period of up to 1 ms. fTx=Nint*128Δf+Nfrac*Δf+Δoffset, and phase compensation is not implemented for Nint*128Δf. Therefore, in the NR system, the phase compensation term ψRx,l=2πfRx(tstart,l+NCP,lμTc) may be calculated as follows.
ψRx,l=2π(NfracΔf+Δoffset)·(tstart,l+NCP,lμTc) Equation 21
When the receiving side operation is defined using the original definition of carrier frequency fRx=NRx*Δf+Δoffset, then the receiving side operation according to Implementation 1 may be expressed as Equation 22 below.
In Equation 22, the integral represents a function corresponding to the FFT, and the operation of Equation 22 may be expressed as shown in
The difference between the examples of
After performing downconversion on the received signal using fRx or performing downconversion and FFT on the received signal using fRx, the receiving side performs phase reset of performing multiplication on the signal at every symbol by using one complex-valued sequence calculated by the carrier frequency fRx, among the 128 complex-valued sequences or among the 128*3 complex-valued sequences.
The transmitting device and the receiving device according to Implementation 1 may store
sequences, or
sequences (corresponding to the value of 2π(NfracΔf+Δoffset) from ψRx,l=2π(NfracΔf+Δoffset)·(tstart,l+NCP,lμTc) excluding (tstart,l+NCP,lμTc)), and use the same upon performing phase reset for each symbol. (tstart,l+NCP,lμTc) has certain values for a subcarrier spacing. Therefore, if the values of 2π(NfracΔf+Δoffset) are fixed to the
sequences according to Implementation 1 of the present disclosure, the phase compensation for the corresponding symbol on a symbol-by-symbol basis may be performed by simply selecting one of the sequences, and therefore phase reset may be easily implemented in the transmitting device and the receiving device.
As such, according to some implementations of the present disclosure, when the carrier frequency is changed, the sequence for phase compensation may also be changed, but the changed sequence is one of only 128 or 128*3 possible sequences. Therefore, in some implementations of the present disclosure, each of the transmitting side and the receiving side may store a sequence composed of phase compensation values to be applied to OFDM symbols corresponding to a positive integer multiple of a period in which phase changes, for each available carrier frequency, and perform phase compensation by applying a sequence corresponding to a specific carrier frequency in every period during processing of OFDM symbol signals using the specific carrier frequency.
For example, if the phase of the OFDM symbols changes with a periodicity of 1 ms and 14 OFDM symbols are included in the 1 ms period, then the phase compensation value sequence for a specific carrier frequency is composed of 14 phase compensation values for each of the 14 OFDM symbols. The transmitting side and the receiving side may store a phase compensation value sequence to be applied at intervals of 1 ms for each carrier frequency, and may use a stored phase compensation value sequence to perform phase compensation on the corresponding carrier frequency.
Implementation 2.
Similar to Implementation 1, Implementation 2 also uses a base carrier frequency of fbase Nint*128Δf to facilitate performing phase reset or to facilitate addressing phase mismatch between OFDM symbols. Here, the term fbase is a frequency that is closest to fXX (where the subscript XX is TX for the transmitting side and Rx for the receiving side) among the frequencies which are integer multiples of 128Δf (e.g., among frequencies less than or equal to fXX or among frequencies greater than or equal to fXX or among frequencies on both sides of fTX). Hereinafter, fbase is represented by Nint*128Δf (where Nint is an integer).
By way of comparison, in Implementation 1 described above, the carrier frequency fTx, was used for frequency upconversion using a free-running OSC (i.e., an analog OSC) and the carrier frequency fib, is used for frequency downconversion using the free-running OSC.
By contrast, in Implementation 2, the base carrier frequency fbase=Nint*128Δf of fXX is used to perform frequency shift (e.g., frequency shift with a free-running OSC) at the analog stage, and the frequency difference ‘fXX−Nint*128Δf’ of fXX is used to perform frequency shift at the digital stage. When Nint*128Δf is used as the upconversion/downconversion frequency in the free-running OSC, the same phase shift value is given for the OFDM symbols (i.e., the phases at the beginning of the signal parts of the OFDM symbols are the same). Therefore, when Nint*128Δf is used as the upconversion/downconversion frequency in the free-running OSC, it may not be necessary to calculate and apply a phase shift value per OFDM symbol for phase compensation.
Hereinafter, two examples of Implementation 2 will be described as Implementation 2-1 and Implementation 2-2 according to a module to be used to frequency-shift ‘fXX−Nint*128Δf’ in the digital stage.
Implementation 2-1
When the final transmitter signal is summarized using Equation 17, the transmitted signal of the transmitter can be expressed by the following equation.
Referring to the last line of Equation 24, Nfrac=modulo(NTx,128) is a term for changing a mapping position of a resource (i.e., a mapping position of a subcarrier) in an IFFT term. That is, in the term
corresponding to the IFFT term, the term k+k0+Nfrac−Ngridsize,μNscRB/2 denotes the mapping position of a resource for IFFT. Thus, the frequency to which the signal symbol ak of each susbcarrier is to be modulated is determined depending on the value of k+k0+Nfrac−Ngridsize,μNscRB/2.
As such, in Implementation 2-1, the baseband signal is frequency-shifted by ‘fTx−Nint*128Δf’ (or a part of ‘fTx−Nint*128Δf’ if Δoffset is not 0) of fTx by changing the mapping position of the resource with respect to the IFFT by Nfrac. Since the IFFT itself has a function to reset the phase, the frequency shift performed by changing the resource mapping position with respect to the IFFT does not cause phase mismatch between the OFDM symbols. The term ej2πΔ
In some scenarios, it is generally difficult to digitally implement a very large frequency shift. By contrast, frequency shift by Δoffset may be easily implemented by a digital OSC since the value of Δoffset is small. The frequency shift by Δoffset is performed after IFFT. In the last line of Equation 24, the frequency fbase in the expression ej2πf
Implementation 1, described above, configured the phase compensation function to perform phase compensation using one of a specific number of complex-valued sequences (e.g., 128 or 128*3 complex-valued sequences). In particular, in Implementation 1, described above, frequency upconversion to the carrier frequency fTx was performed by an analog OSC. By contrast, in Implementation 2-1, frequency up-shift to the carrier frequency fTx is actually performed through frequency shift of (fTx−Nint*128Δf) using IFFT, which is a digital module, and frequency shift of Nint*128Δf using an analog OSC.
Referring to
Corresponding operations may be configured at the receiving side. The receiving side operation according to Implementation 2 will be described in detail below.
The final receiver signal summarized using Equation 20 may be given as follows.
Referring to the last line of Equation 25, Nfrac=modulo(NRx, 128) is a term for changing the de-mapping position of a resource in the FFT term. That is, in the FFT expression
the term k+k0,Rx+Nfrac−Ngridsize,μNscRB/2 is a term relating to the de-mapping position of a resource, i.e., the de-mapping position of a subcarrier to an OFDM baseband signal. In other words, k+k0,Rx+Nfrac−Ngridsize,μNscRB/2 is a term relating to the output positions of the subcarriers from the FFT. In Implementation 2-1, frequency shift is performed by ‘fRx−Nint*128Δf’ (or ‘fTx−Nint*128Δf’ if Δoffset is not 0) of fRx by changing the de-mapping position of the resource with respect to the FFT through Nfrac. Since the FFT itself has a function to reset the phase, the frequency shift performed by changing the resource de-mapping position with respect to the FFT does not cause phase mismatch between the OFDM symbols. The expression e−j2πΔ
In some scenarios, it may be difficult to digitally implement a very large frequency shift. By contrast, frequency shift by Δoffset may be easily implemented by a digital OSC since the value of Δoffset is small. The frequency shift by Δoffset performed before FFT. In the last line of offset is Equation 25, the frequency fbase in the expression e−j2πf
Implementation 1, described above, configured the phase compensation function to perform phase compensation using one of a specific number of complex-valued sequences (e.g., 128 or 128*3 complex-valued sequences). In particular, in Implementation 1, described above, frequency downconversion from the carrier frequency fRx was performed by an analog OSC.
By contrast, in Implementation 2-1 described herein, frequency down-shift from the carrier frequency fRx is actually performed by a frequency shift of ‘fRx−Nint*128Δf’ using FFT, which is a digital module, and frequency shift of fbase−Nint*128Δf using an analog OSC.
Referring to
Implementation 2-2
In Implementation 2-2, as in Implementation 2-1 described above, frequency shift of fbase of the carrier frequency fXX is performed using an analog OSC. However, in Implementation 2-2, frequency shifting of ‘fXX−fbase’ of fXX (which was performed using IFFT/FFT in Implementation 2-1) is performed by the digital OSC.
For example, frequency shift by the digital OSC may be performed by the digital OSC multiplying a signal by a cosine value or a sine value. In this case, the digital oscillator may obtain the cosine/sine value by any appropriate technique, for example by reading the cosine/sine value from a computer memory, or by calculating the cosine/sine value. In order to make the phase of the signal have a certain value at a specific point in time, a digital OSC only needs to be configured such that an address of a memory read by the digital OSC for a specific sample is the address of the memory that stores a cosine/sine value that makes the phase be the certain value. Alternatively, if the digital OSC is implemented to calculate a cosine/sine value rather than reading it from the memory, then the digital oscillator only needs to adjust the phase to a desired value at a specific point in time. That is, the digital OSC may be implemented to read a memory address storing a frequency shift value having the certain phase value for a specific point in time/sample or to adjust the phase to the certain phase value for the specific point in time/sample. Therefore, for the frequency shift by the digital OSC, such implementations may simplify the phase reset function based on the OFDM symbol boundary. In such scenarios, some implementations may not need to perform phase pre-compensation at the transmitting end.
For reference, phase mismatch between OFDM symbols may result from the difference between the time interval during which IFFT/FFT is applied and the time interval during which the free-running OSC is running. Implementing the upconversion/downconversion frequency with a digital OSC instead of a free-running OSC, which is an analog OSC, may enable easier and simpler resetting of the phase at the boundary of OFDM symbols. However, upconversion/downconversion to the extent of the carrier frequency by the digital OSC may cause a very high complexity because the transmitter and the receiver may need to perform multiplication in units of several GHz. For example, to perform upconversion/downconversion to/from 2 GHz using a digital OSC, sampling should be performed in units of at least 4 GHz according to the Nyquist sampling theorem. Accordingly, the digital OSC must be implemented to multiply the input signal by the cosine/sine value of upconversion/downconversion on the basis of the sampling unit of 4 GHz. Implementing such a large number of multiplication operations with a digital module may be very complex in some scenarios, and may lead to an increase in the manufacturing cost of the transmitter and the receiver. Thus, in some scenarios, the overall magnitude of the carrier frequency is not up-converted/down-converted by the digital OSC.
By way of comparison, in Implementation 2-1, described above, the transmitting side is configured to perform a process of upconversion to a frequency corresponding to fbase by the OSC of the RF stage (i.e., the free-running OSC) and a process of determining the position of resource mapping in the IFFT using ffrac (or ‘fTx−fbase’). In scenarios where Δoffset is not 0, the is transmitting side according to Implementation 2-1, described above, may further perform the step of resetting the phase on the OFDM symbol-by-symbol basis (e.g. to have the zero phase at the end time of the cyclic prefix CP) using a digital OSC for Δoffset. In some scenarios of Implementation 2-1, described above, the signal output in the baseband may become asymmetric with respect to DC depending on the value of ffrac (or ‘fTx−fbase’). This may limit the efficiency of the spectrum by filtering after the IFFT output in the transmitter (or before the input of the FFT in the receiver). For example, a portion of the output of the IFFT (or an input of FFT) may be outside of the filtering region of the transmitter (or receiver), resulting in signal distortion at the band edges due to filtering.
Thus, to address such problems, in some scenarios it may be desirable to modify the transmitting side operations of Implementation 2-1 for implementing the function of frequency upconversion (i.e., frequency up-shift) and phase reset corresponding to ffrac (or ‘fTx−fbase’) through the position of resource mapping of the IFFT.
Accordingly, to this end, in Implementation 2-2 described herein, at the transmitting side, the function of frequency shift and phase reset for a frequency corresponding to ffrac (or ‘fTx−fbase’) are configured with a digital OSC as in the case of frequency shift in
Further examples of the above-described scenarios are provided with reference to
Referring to the left part of
By contrast, referring to the right part of
In order to address this issue, as shown in
Referring first to
Referring to
By comparison, in Implementation 2-1 described above, the receiving side is configured to perform a process of downconversion with a frequency corresponding to fbase by the OSC of the RF stage (i.e., the free-running OSC) and a process of determining the position of resource de-mapping in the FFT using ffrac (or ‘fRx−fbase’). If the value of A not 0, then the offset is receiving side according to Implementation 2-1, described above, may perform the process of resetting phase on the OFDM symbol-by-symbol basis (e.g. to have the zero phase at the end time of the cyclic prefix CP) using a digital OSC for Δoffset. In some scenarios of Implementation 2-1 described above, the degree of asymmetry of the signal output in the RF downconversion step may be large with respect to DC depending on the value of ffrac (or ‘fRx−fbase’). This may limit the efficiency of the spectrum by filtering at the downconversion output stage of the receiver.
Thus, to address such problems, in some scenarios it may be desirable to modify the receiving side operations of Implementation 2-1 for implementing frequency downconversion (i.e., frequency down-shift) and phase reset corresponding to ffrac (or ‘fRx−fbase’) through the position of the resource mapping of the FFT.
Accordingly, to this end, in Implementation 2-2, at the receiving side, the function of frequency shift and phase reset for a frequency corresponding to ffrac (or ‘fRx−fbase’) are configured with a digital OSC as in the case of frequency shift in
Implementation 3
Equation 24, above, may be modified as follows.
Based on the last line of Equation 26, Implementation 3 of the present disclosure will be described. Implementation 3 and Implementation 2-1 have similarities in that, for example, Nfrac=modulo(NTx,128) plays the same role in Implementation 3 as in Implementation 2-1. Referring to
corresponds to the IFFT term. In the IFFT term, k+k0+Nfrac−Ngridsize,μNscRB/2 denotes the mapping position of a resource for IFFT.
Referring to ej2π(f
The expression ej2π(f
By way of comparison, Implementation 2, described above, shifted the frequency on a sample-by-sample basis by rotating the phase (i.e., shifting the phase) on a sample-by-sample basis for frequency shift by Δoffset. That is, Implementation 2, described above, utilized a complex value derived on a sample-by-sample basis to rotate the phase on a sample-by-sample basis. By contrast, Implementation 3 only multiplies the output of the IFFT by a fixed complex value on an OFDM symbol-by-symbol basis, as shown in
Furthermore, by way of comparison, Implementation 1, described above, utilized 128 or 128*3 complex-valued sequences for phase compensation for all available carrier frequency candidates. That is, since Implementation 1 utilizes one of 128 or 128*3 complex values per symbol for each carrier frequency, Implementation 1 utilizes 128 or 128*3 complex-valued sequences for phase compensation according to carrier frequencies. By contrast, Implementation 3 does not utilize 128 or 128*3 complex-valued sequences for ffrac because Implementation 3 performs frequency shift by ffrac by changing the resource mapping position to IFFT, and only performs phase compensation for Δoffset that is implemented through analog frequency upconversion. Therefore, since Implementation 3 only performs phase compensation for Δoffset=−5 kHz or Δoffset=5 kHz, it utilizes only two complex-valued sequences for phase compensation for Δoffset=+/−5 kHz. Since the negative frequency corresponds to the opposite phase of a positive frequency, Implementation 3 actually utilizes only one complex-valued sequence for phase compensation. In some implementations, in the case of frequency ranges FR2 and FR1 (>3 GHz) or in the case of Δoffset=0 in frequency range FR1 (<3 GHz), the function of upconversion to the carrier frequency may be configured without any additional operation (e.g., frequency shift by Δoffset) other than IFFT and upconversion, as in the case of Implementation 2.
Implementation 3 is applicable to the receiving side as well as the transmitting side. Equation 25 may be modified into the following equation.
Based on the last line of Equation 27, Implementation 3 of the present disclosure will be described. Implementation 3 and Implementation 2-1 have some similarities in that, for example, Nfrac=modulo(NRx,128) plays the same role in both Implementation 3 and Implementation 2-1. Referring to
corresponds to the FFT term. In the FFT term, k+k0,Rx+Nfrac−Ngridsize,μNscRB/2 denotes the de-mapping position of a resource (e.g., a subcarrier) by FFT. As such, k+k0,Rx+Nfrac−Ngridsize,μNscRB/2 is a term relating to the output positions of subcarriers from the FFT.
Referring to e−j2π(f
The expression e−j2π(f
By way of comparison, Implementation 2 shifts the frequency on a sample-by-sample basis by rotating the phase on a sample-by-sample basis for frequency shift by Δoffset. That is, Implementation 2 implements a complex value derived on a sample-by-sample basis to rotate the phase on a sample-by-sample basis. By contrast, Implementation 3 only multiplies the input to the FFT by a fixed complex value on an OFDM symbol-by-symbol basis.
In addition, by way of comparison, Implementation 1 utilizes 128 or 128*3 complex-valued sequences for phase compensation for all available carrier frequency candidates. That is, since Implementation 1 utilizes one of 128 or 128*3 complex values per symbol for each carrier frequency, Implementation 1 utilizes 128 or 128*3 complex-valued sequences for phase compensation according to carrier frequencies. By contrast, Implementation 3 does not utilize 128 or 128*3 complex-valued sequences for ffrac because Implementation 3 performs frequency shift by ffrac by changing the resource de-mapping position from the FFT, and only performs phase compensation for Δoffset that is implemented through analog frequency downconversion. Therefore, Implementation 3 utilizes only two complex-valued sequences corresponding to +/−5 kHz for phase compensation for Δoffset=+/−5 kHz. In addition, since the negative frequency corresponds to the opposite phase of a positive frequency, Implementation 3 actually utilizes only one complex-valued sequence for phase compensation. In some implementations, in the case of frequency ranges FR2 and FR1 (>3 GHz) or in the case of Δoffset=0 in frequency range FR1 (<3 GHz), the function of downconversion from the carrier frequency may be configured without any additional operation (e.g., frequency shift by Δoffset) other than FFT and downconversion, as in the case of Implementation 2.
The implementations described above (Implementation 1, Implementation 2 and Implementation 3) have been discussed for scenarios where phase compensation for phase discontinuity is performed on the carrier frequency fTx of the transmitting side and the carrier frequency fRx of the receiving side. However, referring to Equation 16, above, the phase compensation ultimately corresponds to correcting the phase discontinuity (i.e., phase mismatch) corresponding to fTx−fRx. Since fTx and fRx correspond to positions of subcarriers (e.g., integer multiples of the subcarrier spacing), phase compensation may also be performed in scenarios where Δoffset is considered to be zero. For example, even if Δoffset is not actually equal to 0, an assumption of Δoffset being equal to 0 may be correspond to the scenario of phase correction/compensation for Δoffset not being performed. As such, implementations of the present disclosure may also be applied to a case where Δoffset is considered to be 0. If Δoffset is considered to be equal to 0, then phase compensation may be performed only for the frequency magnitudes except Δoffset at the carrier frequency at the transmitting side and the receiving side. In scenarios where Δoffset is considered to be 0 in the phase compensation term, the equality fTx=NTx*Δf holds, and therefore the terms ψTx,l=−2πfTx(tstart,l+NCP,lμTc) and ψRx,l=2πfRx(tstart,l+NCP,lμTc) corresponding to phase compensation in the last line of Equation 16 may be expressed as follows.
ψTx,l=−2π(NTxΔf)·(tstart,l+NCP,lμTc) Equation 28
ψRx,l=2π(NTxΔf)·(tstart,lNCP,lμTc) Equation 29
In Equation 28, the following equalities hold: fTx=NTx*Δf+Δoffset=Nint*128Δf+Nfrac*Δf+Δoffset=fbase+Nfrac*Δf+Δoffset=fbase+ffrac+Δoffset. Furthermore, in Equation 29, the following equalities hold: fRx=NRx*Δf+Δoffset=Nint*128Δf+Nfrac*Δf+Δoffset=fbase+Nfrac*Δf+Δoffset=fbase+ffrac+Δoffset. The OFDM symbol signal generation/recovery according to the present disclosure, which is performed assuming Δoffset to be 0, may be applied similarly to Implementation 1, Implementation 2-1, and Implementation 2-2 described above, except that phase compensation for Δoffset is not performed assuming that Δoffset is 0.
In such scenarios, Implementation 1, Implementation 2-1, Implementation 2-2, and Implementation 3 may be implemented as follows, corresponding to Implementation a1, Implementation a2-1, Implementation a2-2, and Implementation a3, respectively.
Implementation a1
Equation 19 relating to the transmitting side of Implementation 1 is given below again.
The phase compensation term of Implementation 1 is given by ψTx,l=−2π(NfracΔf+Δoffset)·(tstart,l+NCP,lμTc), but the phase compensation term of Implementation a1, which does not consider Δoffset, is given by ψTx,l=−2π(NfracΔf)·(tstart,l+NCP,lμTc).
Among Equations 22 and 23 relating to the receiving side of Implementation 1, Equation 23 is given below again.
The phase compensation term of Implementation 1 is given by ψRx,l=2π(NfracΔf+Δoffset)·(tstart,l+NCP,lμTc), but the phase compensation term of Implementation a1 is given by ψRx,l=2π(NRxΔf)·(tstart,l+NCP,lμTc) in scenarios where Δoffset is not considered.
Phase compensation of Implementation 1 is performed using one of 128*3 complex-valued sequences for a frequency band where Δoffset may be −5 kHz, 0 or +5 kHz, for example. By contrast, phase compensation of Implementation a1 is performed using one of 128 complex valued sequences, regardless of Δoffset. In Implementation a1, even if the frequency shift for Δoffset is performed by an analog free-running OSC, phase compensation is not performed to correct phase mismatch that may occur due to Δoffset.
Implementation a2-1.
Considering that phase compensation is performed only for components other than Δoffset, Equation 24 relating to the transmitting side of Implementation 2-1 may be changed to the following equation.
The first line of Equation 32 may be obtained by substituting fbase+ffrac+Δoffset for FTx in the first line of Equation 24. As seen from Equation 32, the phase compensation of Implementation a2-1 may be performed by changing the mapping position of a resource (corresponding to the term k+k0+Nfrac−Ngridsize,μNscRB/2) in the IFFT term
and performing upconversion (corresponding to the term ej2π(f
Analogously, considering that phase compensation is performed only for components other than Δoffset, Equation 25 relating to the receiving side in Implementation 2-1 may be modified to the following equation.
The first line of Equation 33 may be obtained by substituting fbase+ffrac+Δoffset for fRx in the first line of Equation 25. As can be seen from Equation 33, the phase compensation of Implementation 2-1a includes changing the de-mapping position of a resource (corresponding to the term k+k0,Rx+Nfrac−Ngridsize,μNscRB/2) in the FFT term
and downconversion (corresponding to the term ej2π(f
Implementation a2-2
Referring first to
By way of comparison, in Implementation a2-1 described above, at the transmitter side, the frequency corresponding to fbase and Δoffset is used for the upconversion process by the OSC of the RF stage (the free-running OSC) at the transmitting side, and the portion corresponding to ffrac is used in the process of determining the resource mapping position with respect to the IFFT. However, in some scenarios of Implementation a2-1, described above, the degree of asymmetry of a signal output in the baseband may be increased with respect to DC depending on the value of ffrac. This may limit the efficiency of the spectrum by filtering after the IFFT output in the transmitter (or before the input of the FFT in the receiver).
Therefore, to address such problems, in some scenarios it may be desirable to modify the transmitting side operations of Implementation a2-1, described above, for implementing the function of frequency upconversion to ffrac (i.e., frequency up-shift by ffrac) and phase reset by adjusting the position of the resource mapping of IFFT.
Accordingly, to this end, in Implementation a2-2, at the transmitter side, the function of frequency shift by ffrac and phase reset may be realized by a digital OSC. As such, as illustrated in
Referring next to
By way of comparison, in Implementation a2-1 described above, at the receiving side, the frequency corresponding to fbase and Δoffset is used for the downconversion process by the OSC of the RF stage (the free-running OSC) at the receiving side, and the portion corresponding to ffrac is used in the process of determining the resource de-mapping position with respect to the FFT. However, in some scenarios of Implementation a2-1, described above, the degree of asymmetry of a signal (i.e., the RF output) output in downconversion may be increased with respect to DC depending on the value of ffrac. This may limit the efficiency of the spectrum by filtering after downconversion output in the receiver (or before the input of the FFT in the receiver).
Therefore, to address such problems, in some scenarios it may be desirable to modify the receiving side operations of Implementation a2-1, described above, for implementing the function of frequency downconversion (i.e., frequency down-shift) and phase reset corresponding to ffrac by adjusting the position of the resource de-mapping of the FFT.
Accordingly, to this end, in Implementation a2-2, at the receiving side, the function of frequency shift by ffrac and phase reset may be realized by a digital OSC. As such, as illustrated in
To recap, Implementation 1, Implementation 2, and Implementation 3 are briefly summarized below.
Implementation 1 predetermines 128 compensation-valued sequences (or 128*3 compensation-valued sequences if there are three values of Δoffset) for phase compensation, and performs phase compensation on the corresponding OFDM symbol using one compensation-valued sequence for the corresponding carrier frequency among 128 or 128*3 predetermined compensation-valued sequences.
In Implementation 2, an integer multiple of 128Δf is used as the base carrier frequency fbase in both Implementation 2-1 and Implementation 2-2, and frequency up/down-shift is performed by fbase by the free-running OSC at the RF stage. In Implementation 2, the transmitting side compensates for the frequency difference between fTx and fbase by resource mapping for IFFT (Implementation 2-1), or compensates for the difference by frequency shift using the digital OSC after IFFT (Implementation 2-2). The receiving side of Implementation 2 compensates for the frequency difference between fTx and fbase by resource de-mapping for FFT (Implementation 2-1), or compensates for the difference by frequency shift using the digital OSC before FFT (Implementation 2-2).
Implementation 3 is similar to Implementation 2 except that Implementation 3 performs phase compensation for Δoffset on an OFDM symbol-by-symbol basis, unlike Implementation 2, which resets the phase on a sample-by-sample basis for frequency shift by Δoffset.
As described above, in order to prevent phase mismatch between OFDM symbols or to facilitate phase compensation, a frequency corresponding to an integer multiple of 128Δf is used by an analog OSC in the process of OFDM symbol signal generation or OFDM symbol signal recovery. For example, when a numerology of a frequency band supporting a plurality of numerologies is changed, for example, when the subcarrier spacing (SCS) of the frequency band is changed from 30 kHz to 15 kHz, or vice versa, frequencies which are integer multiples of 128Δf may be mismatched. For example, suppose that a frequency corresponding to an integer multiple of 128Δf closest to fTx is fbase,l when Δf=30 kHz (where fbase,l=Nint,l*128Δf for Δf=30 kHz). If the SCS changes from Δf=30 kHz to Δf=15 kHz in the same frequency band as fTx, the frequency fbase,0 corresponding to an integer multiple of 128Δf closest to the upconversion frequency fTx when Δf=15 kHz (where fbase,0=Nint,0*128Δf for Δf=15 kHz) may differ from fbase,l by Δfbase. Alternatively, the upconversion/downconversion frequency may be varied by Δbase according to change in SCS. In this case, the transmitter and the receiver of the present disclosure may compensate for Δbase using a digital OSC or IFFT/FFT resource mapping/de-mapping according to Implementation 2 of the present disclosure described above, rather than performing RF retuning.
Referring to
Since the signals input to the digital-to-analog converter in the transmitter are digital signals and the signals output from the digital-to-analog converter are analog signals, the transmitter modules used for signal processing before the digital-to-analog converter may be digital modules, and the transmitter modules used for signal processing after the digital-to-analog converter may be analog modules.
The receiver performs an operation corresponding to the inverse process of the transmitter. In the receiver operations, a signal that the transmitter transmits is received by the receiver through the antenna, amplifier and analog filter of the receiver. Referring to
Since the signals input to the analog-to-digital converter in the receiver are analog signals and the signals output from the analog-to-digital converter are digital signals, the receiver modules used for signal processing before the analog-to-digital converter may be analog modules, and the receiver modules used for signal processing after the analog-to-digital converter may be digital modules.
Although not shown in
The transmitting device 10 and the receiving device 20 respectively include radio frequency (RF) units 13 and 23 capable of transmitting and receiving radio signals carrying information, data, signals, and/or messages, memories 12 and 22 for storing information related to communication in a wireless communication system, and processors 11 and 21 operationally connected to elements such as the RF units 13 and 23 and the memories 12 and 22 to control the elements and configured to control the memories 12 and 22 and/or the RF units 13 and 23 so that a corresponding device may perform at least one of the above-described implementations of the present disclosure.
The memories 12 and 22 may store programs for processing and controlling the processors 11 and 21 and may temporarily store input/output information. The memories 12 and 22 may be used as buffers.
The processors 11 and 21 generally control the overall operation of various modules in the transmitting device and the receiving device. Especially, the processors 11 and 21 may perform various control functions to implement the present disclosure. The processors 11 and 21 may be referred to as controllers, microcontrollers, microprocessors, or microcomputers. The processors 11 and 21 may be implemented by hardware, firmware, software, or a combination thereof. In a hardware configuration, application specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), or field programmable gate arrays (FPGAs) may be included in the processors 11 and 21. In some implementations, if the present disclosure is implemented using firmware or software, the firmware or software may be configured to include modules, procedures, functions, etc. performing the functions or operations of the present disclosure. Firmware or software configured to perform the present disclosure may be included in the processors 11 and 21 or stored in the memories 12 and 22 so as to be driven by the processors 11 and 21.
In some scenarios of the present disclosure, functions, procedures, and/or methods disclosed in the present disclosure may be implemented by a processing chip (also referred to as a processing device). The processing chip may be a system on chip (SoC). The processing chip may include the processor 11 and/or 21 and the memory 12 and/or 22, and may be mounted on, installed on, or connected to the transmitting device 10 or the receiving device 20. The processing chip may be configured to perform or control any one of the methods and/or processes described herein and/or to cause such methods and/or processes to be performed by a communication device which the processing chip is mounted on, installed on, or connected to. The memories 12 and 22 in the processing chip may be configured to store software codes including instructions that, when executed by the processor, causes the processors 11 and 21 to perform some or all of functions, methods or processes discussed in the present disclosure. The memories 12 and 22 in the processing chip may store or buffer information, data or signals generated by the processor of the processing chip or information, data or signals recovered or obtained by the processors 11 and 21 of the processing chip. One or more processes involving transmission or reception of the information, data or signals may be performed by the processors 11 and 21 of the processing chip or under control of the processors 11 and 21 of the processing chip. For example, the RF units 13 and 23 operably connected or coupled to the processing chip may transmit or receive signals containing the information or data under the control of the processor 11 and 21 of the processing chip.
The processor 11 mounted on, installed on, or connected to the transmitting device 10 performs predetermined coding and modulation for a signal and/or data scheduled to be transmitted to the outside by the processor 11 or a scheduler connected with the processor 11, and then transfers the coded and modulated data to the RF unit 13. For example, the processor 11 converts a data stream to be transmitted into K layers through demultiplexing, channel coding, scrambling, and modulation. The coded data stream is also referred to as a codeword and is equivalent to a transport block which is a data block provided by a MAC layer. One transport block (TB) is coded into one codeword and each codeword is transmitted to the receiving device in the form of one or more layers. The processor 11 may determine or generate symbols (hereinafter referred to as information symbols) for bit sequences input according to, for example, a signal generation technique defined in the standard. The processor 11 may determine a carrier frequency for transmission of radio signals. The processor 11 may determine the frequency fbase used for frequency upconversion. The processor 11 may determine the frequency fbase among frequencies which are integer multiples of
based on the carrier frequency. For frequency up-conversion, the RF unit 13 may include an oscillator. The RF unit 13 may include Nt (where Nt is a positive integer) transmit antennas. The RF unit 13 may perform frequency upconversion by an oscillator according to the present disclosure under control of the processor 11 to generate an OFDM symbol signal. For example, in the case of Implementation 2, the processor 11 may control the oscillator (i.e., the analog oscillator) of the RF unit 13 so as to perform upconversion using a frequency that is an integer multiple of
A signal processing process of the receiving device 20 is the reverse of the signal processing process at the transmitting device 10. Under control of the processor 21, the RF unit 23 of the receiving device 20 receives radio signals transmitted by the transmitting device 10. The RF unit 23 may include Nr receive antennas, and the RF unit 23 may perform frequency downconversion of each signal received through the receive antennas by an oscillator according to the present disclosure under control of the processor 21 to recover the baseband signal. The processor 21 may determine a carrier frequency for reception of radio signals. The processor 21 may determine a frequency fbase used for frequency downconversion. The processor 21 may determine the frequency fbase among frequencies which are integer multiples of
based on the carrier frequency. For example, in the case of Implementation 2, the processor 21 may control the oscillator (i.e., the analog oscillator) of the RF unit 23 so as to perform down conversion using a frequency that is an integer multiple of
The RF unit 23 may include an oscillator for frequency downconversion. The processor 21 may perform decoding and demodulation of the radio signal received through the receive antenna to recover data that the transmitting device 10 originally intended to transmit.
The RF units 13 and 23 include one or more antennas. An antenna performs a function for transmitting signals processed by the RF units 13 and 23 to the exterior or receiving radio signals from the exterior to transfer the radio signals to the RF units 13 and 23. The antenna may also be called an antenna port. Each antenna may correspond to one physical antenna or may be configured by a combination of more than one physical antenna element. The signal transmitted from each antenna cannot be further deconstructed by the receiving device 20. An RS transmitted through a corresponding antenna defines an antenna from the view point of the receiving device 20 and enables the receiving device 20 to derive channel estimation for the antenna, irrespective of whether the channel represents a single radio channel from one physical antenna or a composite channel from a plurality of physical antenna elements including the antenna. That is, an antenna is defined such that a channel carrying a symbol of the antenna can be obtained from a channel carrying another symbol of the same antenna. An RF unit supporting a MIMO function of transmitting and receiving data using a plurality of antennas may be connected to two or more antennas.
In the present disclosure, a user equipment (UE), that is, a terminal operates as the transmitting device 10 on the uplink and as the receiving device 20 on the downlink. In the present disclosure, the base station operates as the receiving device 20 on the uplink and as the transmitting device 10 on the downlink.
The processor 11 mounted on, installed on, or connected to the transmitting device 10 may be configured to perform processes according to the present disclosure on a signal to be transmitted, and may control the modules (see
as fbase.
The processor 21 at the receiving device 10 may control the modules (see
as fbase.
The transmitting device 10 may be configured to include
While the transmitting device 10 and the receiving device 20 are separately shown in
Number | Date | Country | Kind |
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10-2018-0039089 | Apr 2018 | KR | national |
10-2018-0079450 | Jul 2018 | KR | national |
This application is a continuation of U.S. application Ser. No. 17/214,137, filed on Mar. 26, 2021, which is a continuation of U.S. application Ser. No. 16/964,287, filed on Jul. 23, 2020, now U.S. Pat. No. 10,999,821, which is a National Stage application under 35 U.S.C. § 371 of International Application No. PCT/KR2018/015249, filed on Dec. 4, 2018, which claims the benefit of Korean Application No. 10-2018-0079450, filed on Jul. 9, 2018, Korean Application No. 10-2018-0039089, filed on Apr. 4, 2018, U.S. Provisional Application No. 62/629,714, filed on Feb. 13, 2018, and U.S. Provisional Application No. 62/621,058, filed on Jan. 24, 2018. The disclosures of the prior applications are incorporated by reference in their entirety.
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20230155876 A1 | May 2023 | US |
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62629714 | Feb 2018 | US | |
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Parent | 17214137 | Mar 2021 | US |
Child | 18156801 | US | |
Parent | 16964287 | US | |
Child | 17214137 | US |