BR132017010803E2 - channel quality measurements for lower link resource allocation - Google Patents

Abstract

in a digital wireless communication system that may employ cdma technology, method and system for obtaining channel quality (cq) measurements for lower link resource allocation, where a user equipment (eu) continuously measures rscp based in communication over a reference channel provided by the network. eu measures iscp of the time span continuously, by setting or rotating and reports cq from the bottom link. the rscp / iscp function over time, or may report some rscp / iscp ratio function such as modulation or combined encoding parameters of all time spaces.

Description

CHANNEL QUALITY MEASUREMENTS FOR LINK RESOURCE ALLOCATION

"Certificate of Addition of Invention of PI 0209624-2, filed May 14, 2002" [001] The present invention relates to digital wireless communication systems and more specifically to communication stations employing multiple technology. code division access (CDMA) using measurement techniques to efficiently determine lower link resource allocation.

In modern wireless communication systems, as the composition of communication traffic has shifted from primarily voice traffic to an ever-increasing share of data traffic, such as for Internet applications, the capacity needs of these systems have increased. Therefore, providing techniques to maximize the capacity of lower link (DL) transmissions is highly desirable.

[003] The propagation loss between a transmitter and a receiver is not fixed or constant. In addition to dependence on loss of propagation over distance, variations are caused by obstructions to the path (or multiple paths) between the transmitter and the receiver, as well as the interaction between the paths. These variations are called fading. In addition, fading varies over time.

[004] In some communication systems, it is customary to transmit at any given time to a specific user, or multiple users among multiple users, who enjoy the most favorable transmission conditions at that time. With these systems, it is necessary to define channel quality that can be estimated for each user periodically in order to transmit to each user at the most appropriate time. Although the selection of the most appropriate timing of the fading point of view is not mandatory, instantaneous path loss should be one of the factors considered in the selection.

[005] One measure of channel quality is instantaneous path loss. Channel quality improves as instant path loss is reduced and channel quality is improved when instant path loss is minimal.

[006] Another measure of channel quality is user-observed interference, as higher interference usually requires higher transmission power. Because transmission power is limited, this results in reduced system capacity. Channel quality (QC) can therefore be defined as the ratio between the power received from a fixed level base station transmission and the received interference. This ratio is inversely proportional to the required transmit power of the base station for user data. Maximizing this ratio through continuous selection of the users with the highest QC (and therefore the lowest path loss and / or interference) at any time tends to increase the overall system capacity over time. of time.

[007] The specific signal that is measured to determine path loss and calculate ratio is not critical. The signal may be, for example, any pilot signal, beacon or even signal conducting data that is transmitted under known or constant power. In some systems, the receiving power is called the received signal code power (RSCP) and the received interference power is called the interference signal code power (ISCP). In the Universal Mobile Telecommunications System (UMTS) frequency division duplex (FDD) standard, for example, the common pilot channel (CPiCH) is measured and the QC is set to CPiCH_RSCP / ISCP. In the UMTS time division duplex (TDD) standard, the headlamp channel (PCCPCH) is measured and the QC is set to PCCPCH_RSCP / ISCP. As channel conditions change rapidly, it is preferable to use short time allocation (ie short time) for each transmission. The measurement information used for allocation must therefore also be accurate.

[008] In some communication systems, it is customary to separate transmissions to users by time, or to separate one type of selective transmission per user over time from other types of transmissions, such as normal voice services and data services. This time separation can be obtained in different ways. A repetitive frame can be divided, for example, into a series of time frames. Each time slot can be allocated to one or more users at a time. In addition, multiple adjacent or non-adjacent time slots can be allocated to one or more users. If a set of one or more time slots is allocated together, it may be referred to as a subchannel.

In time-separated transmission, it is likely that interference in all time slots or subchannels will not be the same. Reporting a single value for all timeframes often results in non-optimal allocation and information in some of the timeframes may be lost. It is therefore desirable to report individual measurements for each time frame.

Summary of the Invention The present invention provides timely QC measurement and signaling of information to the base station as appropriate. The present invention provides various embodiments for measuring and signaling time-span, or subchannel, QC from the UE to the base station. High speed measurements can be taken for all relevant subchannels or time slots, or can be made at a lower speed by selectively reducing the speed at which these measurements are taken.

BRIEF DESCRIPTION OF THE DRAWINGS The objectives of the present invention will become apparent upon consideration of the detailed descriptive report and accompanying figures, in which: Figure 1 is a simplified block diagram of the UMTS architecture. Figure 2 is a simplified block diagram illustrating a UE and a base station for implementing channel quality measurements for lower link resource allocation according to the present invention. Figure 3 is a flow chart of a preferred method of conducting channel quality measurements in the UE for allocating lower link resources according to the present invention and relating these measurements to the base station.

Detailed Description of Preferred Embodiments Preferred embodiments herein are described below with reference to the figures, along which like numerals represent similar elements.

Referring to Figure 1, the UMTS network architecture includes a central network (CN), a UMTS Terrestrial Radio Access Network (UTRAN), and a User Equipment (UE). The two general interfaces are the Iu interface between UTRAN and the central network and the Uu radio interface between UTRAN and the UE. UTRAN consists of several Radio Network Subsystems (RNS) that can be interconnected by an Iur interface. This interconnect allows independent central network procedures between different RNSs. Specific functions of radio access technology can therefore be kept outside the central network. The RNS is further divided into the Radio Network Controller (RNC) and various base stations (Node Bs). The Bs nodes are connected to the RNC by an Iub interface. A Node B can serve one or several cells and typically serves a series of UEs. UTRAN supports FDD mode and TDD mode on the radio interface. For both modes, the same network architecture and protocols are used.

Referring to the block diagram of Figure 2, a preferred communication system (10) for performing the process of obtaining QC measurements for lower link resource allocation according to the principles of the present invention is shown. Communication system (10) comprises a UE (12) and a base station / node B (30) (hereinafter referred to as base station (30)) which are coupled to each other via a wireless radio interface (14).

The UE (12) includes an antenna (16), an isolator or switch (18), a paired filter (20), a reference channel code generator (21), a power metering device (22). ), a time-space interference measurement device (24), a QC transmitter (26) and a QC determination device (28). The antenna (16) is coupled via the isolator / switch (18) to the paired filter (20), which receives the signal from the bottom link and provides output to the power meter (22). The reference channel code generator (21) generates a reference channel code that is applied to the paired filter (20). The power measuring device (22) analyzes the output of the paired filter (20) to determine the lower link signal power level and outputs its power level to the QC determining device (28).

The isolator / switch output (18) is additionally coupled to the spacetime interference measuring device (24), which measures the lower link channel and provides output to a second input of the QC determining device ( 28). The QC meter (28) analyzes the power level emitted by the power meter (22) and the interference level of the time-span interference meter (24) and provides QC measurement to the transmitter. (26). The transmitter (26) is coupled to the antenna (16) via the isolator / switch (18) for wireless RF transmission to the base station (30) via the wireless radio interface (14).

The base station (30) comprises a reference channel transmitter (36), an isolator or switch (34), an antenna (32), a QC receiver (38) and a QC storage device (40). ). Antenna (32) receives UE RF wireless transmission, including QC measurement via wireless radio interface (14) and couples via isolator / switch (34) to the signal received for the channel quality receiver. (38). The received QC measurement is then stored in the QC storage device (40). The reference channel transmitter (36) provides a reference signal, which is transmitted on the bottom link to the UE (12) via the isolator / switch (34) and antenna (32). The transmitter reference lower link signal 36 is used by the UE 12 to create the lower link QC measurement.

It will be appreciated that the above preferred method (50) according to the present invention shown in Figure 3 may be performed by communication systems other than the types shown in Figures 1 and 2 and the present invention is not intended for use. to be limited in this way.

Referring to Figure 3, method (50) may be implemented via a digital communication system (10) as explained with reference to Figures 1 and 2, which comprises a UE (12) which is in communication with a base station (30).

Rapid time-span or subchannel quality estimation is a preferred QC measurement technique employed by the present invention to provide the best performance for lower link allocation (DL), as the base station 30 will hold all the information. needed to select modulation and coding, select the best user (s) and allocate the best time slots or subchannels to them. Although the present invention is applicable to UMTS frequency division duplex (FDD) and time division duplex (TDD) standards, only one example will be described herein. In the FDD standard, for example, the common pilot channel (CPICH) can be measured and divided by a time-span or subchannel interference-code signal (ISCP) power measurement, which is performed in all relevant time slots . In the TDD standard, the physical common pilot channel (PCCPCH) is an example of a measurable channel.

The base station 30 emits a fixed level transmission (step 52), such as a beacon or signal carrying data, by the PCCPCH, hereinafter referred to as the reference channel. It will be appreciated that the reference channel may be any type of fixed level (or known) base station transmission, whether or not a control channel or data channel. It is only necessary that the power of the reference channel be known by the UE (12) at the time of measurement. The UE 12 measures the strength of the received signal code (RSCP) (step 54). The UE (12) then measures the ISCP (step 56). RSCP and / or ISCP can be measured continuously (ie for each frame and timeframe) or on a less frequent basis as discussed below.

There are a number of different alternatives that can be implemented for steps (56) and (54). Alternatively, the UE 12 measures ISCP and / or RSCP at specifically indicated timeframes and in specifically indicated order. Alternatively, the UE 12 measures ISCP and / or RSCP in all time slots in predetermined order or in random order. Alternatively, UE 12 measures ISCP and / or RSCP in randomly identified amount of time slots in random order. As a fourth alternative, the UE 12 rotates the time span measurement. For example, ISCP and / or RSCP are measured at time frames 1 to 4 of the first frame, then time frames 5 to 8 of the subsequent frame and time frames 9 to 12 of the subsequent frame, etc. are measured. By having such inherent flexibility, method 50 according to the present invention can be adapted to the specific needs of the system operator and the specific application.

As discussed above, it is not necessary to have path loss and interference measured using the same time scheme at the same speed. In this way, ISCP can be measured much less frequently than RSCP. ISCP, for example, can be measured according to the fourth alternative of Table 1 and RSCP can be measured according to the second alternative of Table 1.

Table 1 summarizes the different embodiments for UE measurement. It will be appreciated, however, that any combination of dynamic or predetermined selection of time slots and / or order of time slots may be used without departing from the spirit and scope of the present invention.

Returning to Figure 3, regardless of the time slots or order of time slots that were selected and measured, the UE (12) in step 58 determines the lower link QC from the measurements taken and reports lower link QC to base station (30). The QC measurement may comprise the transmission of ISCP (from step 56) and RSCP (from step 54) individually, transmitting the ISCP / RSCP ratio calculated by the UE (12) or may comprise one of several alternatives which will be explained in further detail to follow.

The lower link QC measurement report generated and transmitted by the UE (12) in step (58) is received by the base station (30) in step 60 and is analyzed in step 62 to determine the activity required for subsequent transmissions. to the UE (12), taking into account lower link QC measurements.

The manner in which the UE collects the measurements and transmits the measurement data is typically a tradeoff between the amount of data supplied and the higher amount required to transmit the measurement data back to the base station (30). Measuring and transmitting all ISCP and RSCP data for each selected timeframe, for example, provides most of the information. The disadvantage, however, is the large amount of data that needs to be transmitted and the higher amount required to transmit it.

The object of the present invention is to return accurate and timely QC information by determining the modulation and encoding suitable for use for the lower link channels. As such, there are many different alternatives that can be used by the UE (12) to measure and transmit this information to the base station (30). Table 2 shows the different RSCP and ISCP transmission alternatives for base station (30). ___________ Table 2 _________ ___________________ [0029] The nine alternatives are usually in the order from the need for the largest number of bits to the need for the lowest number of bits to transmit QC information from the UE lower link (12) to base station (30). It will be understood that this relationship is not all inclusive and the present invention should not be limited to the specific alternatives listed and shown in Table 1.

In alternative 1, the UE (12) transmits RSCP and ISCP for each time slot to the base station (30).

In alternative 2, the UE (12) transmits RSCP once per frame and transmits ISCP for each specified time period to base station (30).

In alternative 3, the UE (12) transmits RSCP / ISCP ratio for each specified time to base station (30).

In alternative 4, the UE (12) encodes and transmits the RSCP / ISCP ratio for each time slot specified for the base station (30). Ratio coding reduces the number of bits required to transmit the information.

In alternative 5, the UE (12) transmits the number of soft symbol errors detected by the UE (12) to the base station (30). Soft symbol errors are well known to those skilled in the art as an indication of lower link QC.

In alternative 6, the UE 12 selects the available modulation coding sets (MCS) from RSCP and ISCP measurements and transmits this selection to the base station, which the base station 30 uses for transmission. There is typically a predefined number of MCSs available for a UE, such as 8 (eight) of these sets. Following the UE's measurements of RSCP and ISCP, it calculates which MSCs would sustainably supply the current QC.

In alternative 7, UE 12 combines the coding of QC information for all time slots. Separate coding of the common and differential quality of all time slots or subchannels results in savings of transmitted bits.

In alternative 8, the UE 12 measures and transmits the average QC for all time slots, which is encoded using a larger number of bits, and then transmits the difference of each remaining time slot to the value. using encoded values that contain fewer bits. As an example, 4 (four) or 5 (five) bits can be used to identify the mean value of time slots, while the difference of each time slot or subchannel to the average value needs only 1 (one) or 2 ( two) bits.

In alternative 9, one of the time slots or subchannels is designated a reference point. The QC measurement for this timeframe is transmitted and then for the remaining timeframes, only the differential information needs to be transmitted as indicated for the reference point. Similar to alternative 8, the reference time slot may be 4 (four) or 5 (five) bits and the reference difference for the remaining time slots may be 1 (one) or 2 (two) bits .

In order to reduce power requirements as well as the complexity of implementation required for measurement and processing, it is desirable to minimize the number of measurements and the amount of processing. For systems where the UE (12) must perform measurements at all times, depending on requests from the base station (30), this may impose a high measurement burden on the UE (12) if the number of time slots or subchannels. be big. In situations where interference does not change at the same fading speed, time span measurements can be rotated such that recent interference measurement is available for some time slots, while older information is used for other spaces.

By reducing the number of time frames measured, complexity can be substantially reduced. Large numbers of time frames to be measured result in frequent measurement reports and high complexity. Fewer time span measurements result in less complexity, but less frequent measurement reports, leading to some performance degradation. Commitment can be made according to the needs and / or preferences of the specific application.

Although the present invention has been described in part by detailed references to the preferred embodiment, these details are intended to be instructive and not restrictive. Those skilled in the art will appreciate that many variations can be made on the structure and mode of operation without departing from the spirit and scope of the present invention as described in the teachings herein.

Claims

Claims (20)

1. User Equipment (UE), comprising: - a measuring device configured to perform a plurality of measurements based on the quality of the lower link, characterized in that each of the plurality of measurements is made on a respective measurement resource. bottom link among a plurality of bottom link features; a channel quality determination device configured to: derive a first channel quality indication to indicate channel quality from a plurality of lower link resources; and deriving a plurality of difference indications, each difference indication being between the first channel quality indication and a channel quality indication for one of the plurality of lower link resources; and a transmitting device configured to transmit at least one report including the first channel quality indication and the plurality of difference indications. User Equipment (UE) according to claim 1, further comprising: a receiver configured to receive at least one subsequent lower link transmission associated with at least one modulation and coding set in response to the first channel quality indication and the plurality of transmitted difference indications. User Equipment (UE) according to claim 1, characterized in that each of the plurality of measurements is derived at least from the received power of a reference signal. User Equipment (UE) according to Claim 1, characterized in that, in at least one report, the number of bits used for each of the plurality of difference indications is less than the number of bits. used for the first channel quality indication. User Equipment (UE) according to Claim 4, characterized in that, in at least one report, the number of bits used for each of the plurality of difference indications is two and the number of bits used. for the first channel quality indication is four. 6. User Equipment (UE), comprising a circuit configured to: - perform a plurality of measurements based on lower link quality in a wireless communication system having a repeating frame structure, characterized in that each from the plurality of measurements is made on a respective lower link resource from a plurality of lower link resources; deriving a first channel quality indication to indicate channel quality from a plurality of lower link resources; deriving a plurality of difference indications, each difference indication being between the first channel quality indication and a channel quality indication for one of the plurality of lower link resources; and transmitting at least one report including the first channel quality indication and the plurality of difference indications to a network within a time interval including a plurality of time slots. User Equipment (UE) according to claim 6, characterized in that the circuit is further configured to receive a subsequent lower link transmission associated with at least one modulation and coding set in response to the first one. channel quality indication and the plurality of transmitted difference indications. User Equipment (UE) according to claim 6, characterized in that each of the plurality of measurements is derived at least from the received power of a reference signal. User Equipment (UE) according to Claim 6, characterized in that, in at least one report, the number of bits used for each of the plurality of difference indications is less than the number of bits. used for the first channel quality indication. User Equipment (UE) according to Claim 9, characterized in that, in at least one report, the number of bits used for each of the plurality of difference indications is two and the number of bits used. for the first channel quality indication is four. 11. User Equipment (UE), comprising: - a measuring device configured to perform a plurality of measurements based on lower link quality, characterized in that one or more of the plurality of lower link resources may be allocated on user equipment (UE) for a lower link transmission from the base station; a channel quality determination device configured to: determine a first channel quality indication for the plurality of lower link resources, the first channel quality indication indicating to the base station a modulation and coding set (MSC), and determining a second channel quality indication for each of the plurality of lower link resources, with each second channel quality indication indicating to the base station an MSC for a lower link resource of the plurality. of bottom link resources; a transmitter configured to transmit a channel quality report to the base station, the channel quality report comprising the first channel quality indication and the plurality of second channel quality indications, and each of the second ones. channel quality indications is reported as a differential channel quality over the first channel quality indication; and - a receiver configured to receive at least one lower link resource allocation from the base station, where at least one lower link resource allocation indicating that a lower link transmission should be sent to the user equipment employing one or more. more among the plurality of lower link features. User Equipment (UE) according to claim 11, characterized in that, in the channel quality report, each second channel quality indication is reported using fewer bits than those used to report the first quality indication. of channel. User Equipment (UE) according to claim 11, characterized in that, in the channel quality report, the first channel quality indication is reported using four bits and each second channel quality indication is reported. using two bits. User Equipment (UE) according to claim 11, characterized in that the metering device is configured to perform lower link measurements for the plurality of lower link resources based on reference signals associated with the plurality of lower link features which are known transmitted power levels for the user equipment. User Equipment (UE) according to claim 11, characterized in that each of the plurality of lower link resources corresponds to a time slot or subchannel. User Equipment (UE) according to claim 15, characterized in that the plurality of lower link resources corresponds to a first subchannel, and the first subchannel corresponds to a reference resource. 17. Method for channel quality measurements for lower link resource allocation implemented by a user equipment, the method comprising: - the user equipment performs lower link measurements for a plurality of lower link resources, characterized in that that one or more of the plurality of downlink resources may be allocated to user equipment for downlink transmission from the base station; the user equipment determines a first channel quality indication for the plurality of lower link resources, the first channel quality indication indicating for the base station an MSC for a lower link resource among the plurality of lower link resources. bottom link; the user equipment transmits a channel quality report to the base station, the channel quality report comprising the first channel quality indication and the plurality of second channel quality indications, and each of the second ones. channel quality indications is reported as a differential channel quality over the first channel quality indication; and - the user equipment receives at least one lower link resource allocation from the base station, with at least one lower link resource allocation indicating that a lower link transmission shall be sent to the user equipment employing one or more. among the plurality of bottom link features. Method according to claim 17, characterized in that, in the channel quality report, each second channel quality indication is reported using fewer bits than those used to report the first channel quality indication. Method according to claim 17, characterized in that, in the channel quality report, the first channel quality indication is reported using four bits and each second channel quality indication is reported using two bits. Method according to claim 17, characterized in that the user equipment performs the lower link measurements for the plurality of lower link resources based on the reference signals associated with the plurality of lower link resources which These are transmitted power levels known to the user equipment.