JP2010147823A - Radio communication device, method, and program for estimating communication quality from radio quality - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radio communication device, method, and program for estimating a communication quality taking into consideration an amount of variation and a variation velocity of a radio quality. <P>SOLUTION: The radio communication device is based on an adaptive modulation system in which a transmission speed of a receiving signal is variable in accordance with the radio quality of the receiving signal from a base station. The radio communication device has: a correlation communication quality storing means associating the communication quality with each average value and standard deviation of the radio quality; a demodulating means for outputting the radio quality in the receiving signal; a statistical average value computing means for computing the average value in the radio quality; a statistical standard deviation computing means for computing the standard deviation in the radio quality; and a communication quality estimating means for using the average value output from the statistical average value computing means and the standard deviation output from the statistical standard deviation computing means, and referring to the correlation communication quality storing means to lead the communication quality. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a wireless communication apparatus, method, and program for estimating communication quality from wireless quality for a wireless communication system.

  In a wireless communication system such as a wireless local area network (LAN) and a cellular communication network, adaptive modulation and coding (AMC) that changes a transmission rate according to wireless quality is used. In adaptive modulation, the transmission rate is determined by a combination (MCS: Modulation and Coding Scheme) of the orthogonal modulation scheme of the transmission signal and the coding rate of the error correction code.

  In a wireless communication system using adaptive modulation, a reception-side wireless communication apparatus measures wireless quality using a pilot signal. The reception-side wireless communication device determines a transmission rate at which transmission is possible at a certain error rate or less from the measured value, and feeds back the transmission rate to the transmission-side wireless communication device. The transmitting side wireless communication device transmits the packet at the fed back transmission rate.

  Further, the reception-side wireless communication apparatus can evaluate the service quality that can be received at the location by measuring the communication quality. However, when measuring communication quality, it is necessary to flow traffic through a network including a wireless link. For this reason, frequent measurement of communication quality by many wireless communication apparatuses adds a load to the base station and the network, and may reduce the communication quality of the entire system.

  According to the wireless communication system using adaptive modulation, since the transmission rate is determined based on the wireless quality, the communication quality depends on the wireless quality. Further, since the radio quality can be measured without flowing traffic, no load is applied to the base station and the network. Therefore, techniques for estimating communication quality based on radio quality are being studied. In the following, the “maximum transmission rate” means the upper limit of the transmission rate that can be realized when there is no competing traffic.

  Conventionally, there is a technique for estimating a maximum transmission rate using wireless quality (see, for example, Patent Document 1). According to this technology, pilot signal strength, beacon signal strength, Eb / N0 (Energy per bit to Noise power spectral density ratio), SINR (Signal to Interference and Noise power Ratio), and CIR (Carrier to Interference) are radio quality. The maximum transmission rate is estimated using at least one of power ratio). The association between the radio quality and the maximum transmission rate is defined for each radio access method using an access specifying function that takes the radio quality as an input.

  There is also a technique for deriving a DRC (Data Rate Control) transmission rate by using CIR as radio quality (see, for example, Patent Document 2). According to this technique, a conversion table from CIR to DRC is used. DRC is defined by the modulation scheme and the number of retransmissions of HARQ (Hybrid Automatic Repeat reQuest). The DRC rate is regarded as the maximum transmission rate when retransmitted to the upper limit of HARQ.

  Further, there is a technique for deriving the DRC transmission rate using the received power in addition to the CIR using the technique described in Patent Document 2 (see, for example, Patent Document 3). According to this technique, the maximum transmission rate is calculated using DRC derived from CIR and an index value obtained by comparing received power and a reference value.

Special Table 2007-515123 JP 2004-253832 A JP 2008-113455 A Kamran Etemad, CDMA2000 Evolution: SystemConcepts and Design Principles, a Wiley-Interscience Publication, 2005.

  According to the technique described in Patent Literature 1, the access specific function is used to associate the wireless quality with the maximum transmission rate. However, when the wireless quality varies with time due to the surrounding environment and the movement of the wireless terminal, it is difficult to estimate the accurate communication quality from the wireless quality using only the access specific function. The reason is that the relationship between the radio quality and the communication quality differs depending on the radio quality fluctuation and the fluctuation speed. For example, it is well known that a bit error rate characteristic is greatly different between an AWGN transmission line and a Rayleigh fading transmission line even if the average SINR is the same.

  Further, according to the techniques described in Patent Documents 2 and 3, the DRC estimated from the radio quality is regarded as the maximum transmission rate. However, in an environment where the wireless quality fluctuates, early termination that is normally received occurs before the number of retransmissions reaches the upper limit. Therefore, it is difficult to consider that DRC is equivalent to the maximum transmission rate.

  Accordingly, an object of the present invention is to provide a wireless communication apparatus, method, and program capable of estimating communication quality in consideration of a wireless quality fluctuation amount and a fluctuation speed.

According to the present invention, in a wireless communication apparatus based on an adaptive modulation scheme in which the transmission rate of a received signal is variable according to the wireless quality of the received signal from a base station,
Correlated communication quality storage means that associates communication quality with each of the average value and standard deviation of radio quality;
Demodulation means for outputting radio quality in the received signal;
A statistical average value calculating means for calculating an average value in wireless quality;
Statistical standard deviation calculating means for calculating standard deviation in wireless quality;
Communication quality estimation means for deriving communication quality with reference to the correlated communication quality storage means using the average value output from the statistical average value calculation means and the standard deviation output from the statistical standard deviation calculation means It is characterized by that.

According to another embodiment of the wireless communication device of the present invention,
The correlated communication quality storage means also preferably stores an estimation formula representing a correspondence relationship between the average value and standard deviation of the radio quality and the communication quality.

According to another embodiment of the wireless communication device of the present invention,
The radio quality is a signal-to-interference ratio SINR and / or a transmission rate DRC that can be received at a predetermined error rate or less, and the communication quality is a maximum transmission rate.
The estimation formula of the correlation communication quality storage means is a function that approximately represents the relationship between the average SINR and / or the average DRC and the maximum transmission rate measured when the standard deviation of SINR and / or DRC is changed. Is also preferable.

According to another embodiment of the wireless communication device of the present invention,
The radio quality is a signal-to-interference ratio SINR and a transmission rate DRC that can be received at a predetermined error rate or less, and the communication quality is a maximum transmission rate.
The estimation formula of the correlated communication quality storage means is
From the average value and standard deviation of SINR, the packet error rate PER (Packet Error for each transmission rate DRC)
Rate)
From the average value and standard deviation of SINR, the selection probability that each DRC is selected is calculated,
From the packet error rate PER, calculate the average number of retransmissions for each transmission rate DRC,
It is also preferable to calculate the maximum transmission rate based on the selection probability and the average number of retransmissions.

According to the present invention, in a program for causing a computer mounted on a wireless communication apparatus based on an adaptive modulation scheme based on an adaptive modulation scheme in which a transmission speed of a received signal is variable according to the radio quality of a received signal from a base station,
Correlated communication quality storage means that associates communication quality for each wireless quality average value and standard deviation;
Demodulation means for outputting radio quality in the received signal;
A statistical average value calculating means for calculating an average value in wireless quality;
Statistical standard deviation calculating means for calculating standard deviation in wireless quality;
Using the average value output from the statistical average value calculating means and the standard deviation output from the statistical standard deviation calculating means, the computer is used as a communication quality estimating means for deriving the communication quality by referring to the correlated communication quality storage means. It is made to function.

According to the present invention, in the communication quality estimation method for a wireless communication apparatus based on an adaptive modulation scheme in which the transmission rate of a received signal is variable according to the wireless quality of the received signal from the base station,
For each wireless quality average value and standard deviation, a correlation communication quality storage unit that associates communication quality is provided.
A first step of outputting radio quality in the received signal;
A second step of calculating an average value and standard deviation in radio quality;
A third step of deriving communication quality by referring to the correlated communication quality storage means using the average value output from the statistical average value calculation means and the standard deviation output from the statistical standard deviation calculation means; It is characterized by that.

  According to the wireless communication device, method, and program of the present invention, communication quality can be estimated in consideration of the variation amount and variation rate of wireless quality by using the average value and standard deviation as statistics of wireless quality. .

  Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a functional configuration diagram of a wireless communication apparatus according to the present invention.

  A downlink of a cellular system is assumed as a wireless communication system. According to FIG. 1, the wireless communication apparatus 1 is a mobile phone, for example, and receives a common channel pilot signal from the base station 2. The mobile phone 1 includes a modulation unit 111, an encoding unit 112, a demodulation unit 121, a decoding unit 122, a correlated communication quality storage unit 100, a statistical average value calculation unit 101, a statistical standard deviation calculation unit 102, A communication quality estimation unit 103. These functional components are realized by executing a program that causes a computer mounted on a mobile phone (wireless communication apparatus) to function.

  Demodulation section 121 measures the downlink radio quality using the pilot signal transmitted from base station 2 and outputs the radio quality. The radio quality may be, for example, SINR (Signal / Interference Noise Ratio) or DRC (Data Rate Control bit).

“SINR” is the ratio between the power of the desired signal and the sum of the power of the interference and noise signals. CDMA2000 EV-DO
According to Rev. A, it is expressed as a dB value.

“DRC” is a discrete value based on the transmission rate. According to CDMA2000 EV-DO Rev.A, it is defined by 14 types of DRC Index. Table 1 is a graph showing the relationship between DRC Index and DRC Rate (transmission rate).

  Demodulation section 121 outputs the dB value based on SINR and the DRC Index based on DRC to statistical average value calculation section 101 and statistical standard deviation calculation section 102.

The statistical average value calculation unit 101 and the statistical standard deviation calculation unit 102 receive SINR and DRC from the demodulation unit 121. Here, according to Table 1 based on EV-DO Rev. A, the DRC Index is not arranged in the order of transmission speed. There are a plurality of DRCs having the same transmission rate. According to the present invention, DRC
A DRC Order is newly defined by rearranging Indexes in order of transmission speed.

Table 2 is a graph showing the relationship among DRC Order, DRC Index, and DRC Rate (transmission rate).

  The statistical average value calculation unit 101 and the statistical standard deviation calculation unit 102 derive a transmission rate (DRC Rate) and a DRC Order from the DRC Index.

  The statistical average value calculation unit 101 calculates an average value in wireless quality. Further, the statistical standard deviation calculation unit 102 calculates a standard deviation in radio quality. Here, the radio quality is a dB value based on SINR and a DRC Index based on DRC. The average value of SINR is an average with respect to fluctuation due to Rayleigh fading, and is an average value of several tens to several hundreds of ms. Moreover, the standard deviation of SINR represents the standard deviation in the interval for obtaining the average value.

  The statistical average value calculation unit 101 calculates an average value of dB values based on SINR and an average value of DRC Index based on DRC. The average value and the mean square value may be calculated using a section average, a simple moving average (SMA), or an exponential smoothing moving average (EMA). Further, the statistical standard deviation calculation unit 102 calculates the standard deviation of the dB value based on the SINR and the standard deviation of the DRC Index based on the DRC.

FIG. 2 is a graph showing changes in transmission rate and DRC Order with respect to elapsed time. FIG. 2A shows a change in the transmission rate with respect to the elapsed time, and E _Rate represents an average value of the transmission rates. FIG. 2B shows a change in DRC Order with respect to elapsed time, and E _Order represents an average value of DRC Order.

As is clear from the difference between FIG. 2A and FIG. 2B, the relationship between the DRC variation and the standard deviation of the transmission rate differs depending on the magnitude of the transmission rate. For example, there are the following differences.
DRC Order1-DRC Order2 fluctuation: Transmission rate difference = 38.4 kbps
...
DRC Order10-DRC Order11 fluctuation: Transmission rate difference = 614.4 kbps
...

  In this case, the transmission rate difference between DRC Orders is 16 times. Therefore, when the transition probabilities of DRC fluctuations are equal, the standard deviation of the fluctuation between DRC Orders 1-2 and the fluctuation between DRC Orders 10-11 is 16 times. On the other hand, the standard deviation of DRC Order can be evaluated on the same basis regardless of the transmission speed. Therefore, the communication quality estimation uses the standard deviation of the transmission rate and the standard deviation of the DRC Order.

  The communication quality estimation unit 103 uses the average value output from the statistical average value calculation unit 101 and the standard deviation output from the statistical standard deviation calculation unit 102 to refer to the correlation communication quality storage unit 100 and perform communication. Deriving quality.

  Correlated communication quality storage section 100 stores communication quality associated with each of the average value and standard deviation of radio quality. Here, correlated communication quality storage section 100 stores an estimation expression for outputting the communication quality at the maximum transmission rate from the average value and standard deviation of the radio quality of SINR and DRC. There are two embodiments of the estimation formula, for example.

[First estimation formula]
The first estimation formula is a function that approximately represents the relationship between the average SINR and / or the average DRC and the maximum transmission rate that are actually measured when the SINR and / or DRC standard deviation is changed. First, wireless quality and communication quality are measured in advance simultaneously. At this time, in order to measure the maximum transmission rate as the communication quality, the measurement is performed in an environment where there is no other traffic. Moreover, it is preferable that the environment is such that the average value and the standard deviation of the radio quality become predetermined values. Since the actual measurement points are discrete, a probability model equation that approximates the relationship between the radio quality statistic and the communication quality is calculated using a least square method or the like in order to approximately derive the intermediate point.

  FIG. 3 is a graph showing the relationship of the estimation formula of the maximum transmission rate with respect to the average SINR.

σ _SINR represents the standard deviation of SINR. According to FIG. 3, the maximum transmission rate is plotted against the average SINR at σ _SINR = 0 and σ _SINR = 10. As σ _SINR increases, the maximum transmission rate at the same SINR decreases. By measuring with varying σ _SINR , an estimation formula can be derived in the form of the sum of a polynomial function and an exponential function for the measurement result.

For example, when a quadratic function and an exponential function having a base of 2 are used, an estimation equation for deriving the maximum transmission rate (bps) T from SINR (dB) γ for σ _SINR = 0 is expressed as follows. .
^{T = a {(bγ + c} ) 2 +2 dγ + e}
However, a, b, c, d and e are real constants, respectively.

  FIG. 4 is a graph showing the relationship of the estimation formula of the maximum transmission rate with respect to the average transmission rate (DRC rate).

σ _Order represents the standard deviation of DRC Order. According to FIG. 4, the maximum transmission rate for DRC Order is plotted for σ _Order = 0 and σ _Order = 2. In addition, a plot in which the DRC Order is equal to the maximum transmission rate is drawn with a straight auxiliary line. Maximum transmission rate in the same DRC is significantly different between σ _Order = 0 σ _Order = 2 and. This is based on the fact that HARQ is used in CDMA2000 EV-DO Rev.A. This is because the maximum transmission rate becomes larger than the DRC Order due to Early Termination when the radio quality varies.

When σ _Order = 0, that is, when the DRC Order does not fluctuate, the DRC Order and the maximum transmission rate are in a linear relationship. On the other hand, when σ _Order = 2, the maximum transmission rate is a logarithmic function of DRC Order. Here, an estimation formula is derived in the form of the sum of a linear function and a logarithmic function for the measurement result.

For example, when using a logarithmic function with 2 as a base, an estimation equation for deriving the maximum transmission rate (bps) T from DRC (bps) D with respect to σ _Order = 0 is expressed as follows.
T = aD + log ₂ (bD + c) + d
However, a, b, c and d are real constants and satisfy c> 1.

Note that the estimation formula when σ _SINR = 5 needs to be approximately derived based on the estimation formulas of σ _SINR = 0 and σ _SINR = 10.

[Second estimation formula]
The estimation formula consists of the following four steps.
(S1) The packet error rate PER (Packet Error Rate) for each DRC is calculated from the average value and standard deviation of SINR.
(S2) The selection probability that each DRC is selected is calculated from the average value and standard deviation of SINR.
(S3) The average number of retransmissions for each DRC is calculated from the packet error rate PER.
(S4) The maximum transmission rate is calculated based on the selection probability and the average number of retransmissions.

(S1) The packet error rate PER for each DRC is calculated from the average value and standard deviation of SINR. FIG. 5 is a graph showing the packet error rate PER for each DRC with respect to the _SINR average value Ave _SINR and standard deviation σ _SINR . In addition, for DRCs using the same MCS (combination of orthogonal modulation scheme and error correction coding rate), the slot error rate PER for Ave _SINR and σ _SINR is the same. Under the same condition of Ave _SINR, PER increases as σ _SINR increases. PER characteristics PER _DRC at a DRC is calculated by a function f _DRC.
PER _DRC (Ave _SINR , σ _SINR ) = f _DRC (Ave _SINR , σ _SINR )

(S2) The selection probability that each DRC is selected is calculated from the average value and standard deviation of SINR. FIG. 6 is a graph showing the probability that each DRC is selected with respect to the average value Ave _SINR and the standard deviation σ _SINR of _SINR . The larger the standard deviation σ _SINR , the wider the range of the average value Ave _{SINR from} which a certain DRC is selected. The probability P _DRC that a certain DRC is selected is derived by the function g _DRC .
P _DRC (Ave _SINR , σ _SINR ) = g _DRC (Ave _SINR , σ _SINR )

(S3) The average number of retransmissions for each DRC is calculated from the packet error rate PER.
The average number of retransmissions for each DRC is derived using the PER for each DRC derived from the _SINR average value Ave _SINR and the standard deviation σ _SINR calculated in S1. Using the upper limit Nmax _DRC of the number of packet retransmissions determined for each DRC, the average number of retransmissions _NDRC is derived as follows.
N _DRC (Ave _SINR , σ _SINR ) =
Σ _{i = 1} ^NmaxDRC [i • {1-PER _DRC (Ave _SINR , σ _SINR )} • PER _DRC ^i-1 (Ave _SINR , σ _SINR )]

(S4) The maximum transmission rate is calculated based on the selection probability and the average number of retransmissions.
The expected value of throughput is derived using the probability P _DRC derived in S2 and S3 and the average number of retransmissions N _DRC for each _DRC . In each DRC, the maximum transmission rate R _DRC when no packet error occurs is uniquely defined. Using P _DRC , N _DRC and R _DRC , the expected value R of the throughput is calculated as follows.
R (Ave _SINR , σ _SINR ) =
Σ _{i = 1} ^DRCmax P _i (Ave _SINR , σ _SINR ) ・ R _i / N _i (Ave _SINR , σ _SINR )
DRCmax represents the maximum value of DRC Index. For example, in the case of CDMA2000 1xEV-DO Rev. A, DRCmax = 14. Further, when the average SINR value Ave _SINR and standard deviation σ _SINR are given, the average throughput R is derived.

  As described above in detail, according to the wireless communication apparatus, method, and program of the present invention, by using the average value and the standard deviation as the statistics of the wireless quality, the amount of change and the speed of the wireless quality are considered. Communication quality can be estimated. Specifically, in a wireless communication system using adaptive modulation, the maximum transmission rate can be estimated in consideration of SINR and DRC fluctuation amounts. In particular, by using not only the average value but also the standard deviation as a parameter, it is possible to consider fluctuations in radio quality. Fluctuations in radio quality are approximated by a probability distribution model such as an exponential distribution, the behavior of adaptive modulation and HARQ is theoretically analyzed, and an estimation formula for the maximum transmission rate is derived.

  In the various embodiments of the present invention described above, various changes, modifications, and omissions in the scope of the technical idea and the viewpoint of the present invention can be easily made by those skilled in the art. The above description is merely an example, and is not intended to be restrictive. The invention is limited only as defined in the following claims and the equivalents thereto.

It is a functional block diagram of the radio | wireless communication apparatus in this invention. It is a graph showing the change of the transmission rate with respect to elapsed time and DRC Order. It is a graph showing the relationship of the estimation formula of the maximum transmission rate with respect to average SINR. It is a graph showing the relationship of the estimation formula of the maximum transmission rate with respect to an average DRC rate. It is a graph showing the packet error rate PER for each DRC with respect to the average value Ave _SINR and standard deviation σ _SINR of _SINR . It is a graph showing the probability that each DRC is selected with respect to the average value Ave _SINR and the standard deviation σ _SINR of _SINR .

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Wireless communication apparatus, mobile telephone 2 Base station 111 Modulation part 112 Coding part 121 Demodulation part 122 Decoding part 100 Correlation communication quality memory | storage part 101 Statistical average value calculation part 102 Statistical standard deviation calculation part 103 Communication quality estimation part

Claims (6)

In a wireless communication apparatus based on an adaptive modulation scheme in which the transmission speed of the received signal is variable according to the wireless quality of the received signal from the base station,
Correlated communication quality storage means that associates communication quality with each of the average value and standard deviation of radio quality;
Demodulation means for outputting the wireless quality in the received signal;
Statistical average value calculating means for calculating the average value in the wireless quality;
Statistical standard deviation calculating means for calculating the standard deviation in the wireless quality;
Communication quality for deriving communication quality using the average value output from the statistical average value calculation means and the standard deviation output from the statistical standard deviation calculation means with reference to the correlated communication quality storage means A wireless communication apparatus comprising: an estimation unit.   2. The radio communication apparatus according to claim 1, wherein the correlated communication quality storage unit stores an estimation formula representing a correspondence relationship between the average value and standard deviation of the radio quality and the communication quality. The radio quality is a signal / interference noise ratio (SINR) and / or a transmission rate DRC (Data Rate Control bit) that can be received at a predetermined error rate or less, and the communication quality is a maximum transmission rate. Speed,
The estimation formula of the correlated communication quality storage means is a function that approximately represents the relationship between the average SINR and / or average DRC and the maximum transmission rate measured when the standard deviation of SINR and / or DRC is changed. The wireless communication apparatus according to claim 2, wherein there is a wireless communication apparatus. The radio quality is a signal-to-interference ratio SINR and a transmission rate DRC that can be received at a predetermined error rate or less, and the communication quality is a maximum transmission rate.
The estimation formula of the correlated communication quality storage means is
From the average value and standard deviation of the SINR, a packet error rate PER (Packet Error Rate) for each transmission rate DRC is calculated,
A selection probability that each DRC is selected is calculated from the average value and standard deviation of the SINR,
From the packet error rate PER, calculate the average number of retransmissions for each transmission rate DRC,
The radio communication apparatus according to claim 2, wherein the maximum transmission rate is calculated based on the selection probability and the average number of retransmissions. According to the radio quality of the received signal from the base station, in a program for causing a computer mounted in a wireless communication device based on an adaptive modulation scheme based on an adaptive modulation scheme in which the transmission speed of the received signal is variable,
Correlated communication quality storage means that associates communication quality for each wireless quality average value and standard deviation;
Demodulation means for outputting the wireless quality in the received signal;
Statistical average value calculating means for calculating the average value in the wireless quality;
Statistical standard deviation calculating means for calculating the standard deviation in the wireless quality;
Communication quality for deriving communication quality using the average value output from the statistical average value calculation means and the standard deviation output from the statistical standard deviation calculation means with reference to the correlated communication quality storage means A program for a wireless communication apparatus, which causes a computer to function as estimation means. In a communication quality estimation method for a wireless communication apparatus based on an adaptive modulation scheme in which a transmission rate of the received signal is variable according to the wireless quality of the received signal from a base station,
For each wireless quality average value and standard deviation, a correlation communication quality storage unit that associates communication quality is provided.
A first step of outputting the radio quality in the received signal;
A second step of calculating the average value and the standard deviation in the wireless quality;
The communication quality is derived by referring to the correlated communication quality storage means using the average value output from the statistical average value calculation means and the standard deviation output from the statistical standard deviation calculation means. A communication quality estimation method comprising the steps of:

Images