JP2003264514A - Circuit for measuring receiving level - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a receiving level measuring circuit capable of improving the measuring accuracy of a receiving level by correcting phase rotation resulting from a frequency error of an oscillator provided in a transmitter/ receiver and preventing unproper correction from being performed under a situation that there is no desired wave. <P>SOLUTION: In the receiving level measuring circuit, a desired wave/ interference potential detecting part 9 detects a frequency error vector. An adder 50, a frequency error averaging part 51 and an arctangent operating part 52 add, average and perform unit conversion of frequency error vectors. Correction values corresponding to frequency errors are stored in a frequency error correction table 53 in advance, and a correction value corresponding to a frequency error is acquired. An adder 10 adds a plurality of desired wave components, and a frequency error correcting part 42 corrects the desired wave components by using the correction value. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a receiving level measuring circuit used in a receiver of a mobile communication system, and more particularly to a receiving level measuring circuit capable of improving the receiving level measurement accuracy.

[0002]

2. Description of the Related Art In a mobile communication system, various multiple access methods have been devised as a method for effectively utilizing resources such as limited frequencies.
A method called a Sequence-Code Division Multiple Access method has been drawing attention. CD
In the MA system, in particular, an individual spreading code is assigned and multiplexed for each channel to be communicated, and a pilot symbol is inserted into a transmission symbol for transmission, and an amplitude phase fluctuation is deduced from the despread signal of the pilot symbol on the receiving side. DS-C that extracts and corrects the received symbol using it to detect
DMA (Direct Sequence Code Division Multiple Acc
In the ess: direct sequence code division multiple access system, it is known that the receiver needs to measure the level of the received wave in order to perform the closed loop control type transmission power control peculiar to the system.

First, a configuration example of a reception level measuring circuit in a conventional CDMA receiver will be described with reference to FIG. FIG. 6 is a block diagram showing a configuration example of a conventional reception level measuring circuit. As shown in FIG. 6, a conventional reception level measuring circuit includes an RSSI detecting section 1 and an A / D converting section 2.
And an RSSI averaging unit 3 and a voltage / dB converting unit 4.

Each part of the conventional reception level measuring circuit will be described. The RSSI detector 1 receives the received signal field strength I of the received signal in the radio frequency band.
ndicator (RSSI) is detected and voltage is output. This part is realized by a commercially available IC for RSSI detection or the like. The A / D conversion unit 2 outputs the voltage output R
The SSI analog value is converted into a digital value. The RSSI averaging unit 3 averages the detected RSSIs. The voltage / dB conversion unit 4 converts the averaged RSSI voltage value into a dB value.
This part can be realized by creating a conversion table of the RSSI voltage value to the RSSI dB value in advance and referring to it.

Next, the operation of the conventional level measuring circuit will be described with reference to FIG. In the conventional level measurement circuit,
The received signal in the radio frequency band input to the receiver is RS
The RSSI of the received signal is input to the SI detection unit 1, detected as an analog voltage value, converted into a digital value by the A / D conversion unit 2, and subjected to predetermined averaging by the RSSI averaging unit 3. The voltage / dB converter 4 converts the signal into a dB value, and the measurement result of the reception level of the signal input to the receiver is output as the RSSI dB value. As a result, the reception quality of the signal input to the receiver could be measured.

However, in the above-mentioned conventional reception level measuring circuit, in the DS-CDMA system, since a plurality of transceivers communicate using the same radio frequency band, all the signals input to the receiver are desired. Not limited to the wave level, including the interference wave level,
There is a problem in that it is measured as a single reception level. Further, in the RSSI measurement in the radio frequency band, theoretically, a level lower than the in-band noise of the receiver radio unit cannot be measured, and there is a problem that an accurate reception level cannot be measured at all levels.

As a technique for solving this problem, the Heisei 1
Japanese Unexamined Patent Publication No. 2001-285209, "Reception level measuring method and reception level measuring circuit" (applicant: Hitachi Kokusai Electric Co., Ltd., inventor: Takahito Ishii), proposed on Oct. 12, 2013 is proposed. This conventional technique detects the electric field strength of a received signal, performs quadrature detection of the received signal, detects a desired wave and an interference wave for each spread code from a baseband signal, and combines a plurality of desired wave components to generate power. When the received electric field strength is below the in-band noise, the desired wave level is used as it is, and when it is above the in-band noise, the received electric field strength detected by the radio section is added to the desired wave level. A reception level measuring method and a reception level measuring circuit, which add and correct to obtain a reception level measurement result.

[0008]

SUMMARY OF THE INVENTION The reception level measuring circuit disclosed in Japanese Patent Laid-Open No. 2001-285209, which is the above-mentioned conventional technique, is
The desired wave level and the interference wave level are measured separately, and if the received electric field strength is below a specific value (in-band noise), the desired wave power level is set as the desired wave reception level and exceeds the specified value (in-band). Noise level), the level of the electric field strength is added to the level of the desired wave power to correct it to obtain the desired wave reception level, so the desired wave reception level is measured to a level below the in-band noise of the receiver radio section. It has a basic configuration that can be made possible.

The present invention corrects the phase rotation caused by the frequency error of the oscillator provided in the transceiver and prevents the reception level from being inappropriately corrected in the absence of the desired wave. It is an object of the present invention to provide a reception level measurement circuit that can improve measurement accuracy.

[0010]

According to the present invention, in a reception level measuring circuit, a received signal electric field strength detection means detects the electric field strength of a received signal, and a quadrature detection means carries out quadrature detection of the received signal to obtain a desired wave / interference. The plurality of desired wave components, the plurality of interference wave components, and the plurality of frequency error vectors are detected from the reception signal quadrature detected by the wave detection means, and the frequency error correction value acquisition means stores the correction value corresponding to the frequency error in advance. Well,
A correction value corresponding to the frequency error obtained by adding and averaging a plurality of frequency error vectors detected by the desired wave / interference wave detecting means and unit-converting is obtained, and by the frequency error correcting means,
A plurality of desired wave components detected by the desired wave / interference wave detection means are added, and the desired wave component is corrected using the correction value,
If the desired wave component corrected by the desired wave component power conversion means is converted to electric power and the level of the desired wave power is obtained, and the electric field strength detected by the desired wave level correction means falls below a predetermined specific value, The level of wave power is output as the desired wave reception level, and if the detected electric field strength exceeds a specific value, correction is performed to add the detected electric field strength level to the desired wave power level, and the desired wave reception level is received. Since it is output as a level, the desired wave level and the interference wave level are separated and measured, and the received electric field strength is below a specified value (below the in-band noise)
In the case of, the level of the desired wave power is set as the desired wave reception level, and when it exceeds a specific value (more than in-band noise), the level of the electric field strength is added to the level of the desired wave power to correct it.
When the desired wave reception level is set, the phase rotation due to the frequency error of the oscillator included in the transceiver is corrected to improve the measurement accuracy of the desired wave reception level.

Further, according to the present invention, in the reception level measuring circuit, the interference wave component averaging means averages a plurality of interference wave components detected by the desired wave / interference wave detecting means and outputs the interference wave reception level. The desired wave power to interference wave power ratio measuring means calculates the desired wave power to interference wave power ratio from the interference wave reception level from the interference wave component averaging means and the desired wave power level, and the desired wave level correction means , When the electric field strength detected exceeds a specific value during correction with a specific value as a reference, if the desired wave power to interference wave power ratio is greater than zero, it is detected at the desired wave power level. If the desired wave power to interference wave power ratio is less than or equal to zero, the correction to add the detected electric field strength level to the desired wave power level is not performed. , Hope wave To avoid improper correction in the absence and improve the measurement accuracy of the desired signal component.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described with reference to the drawings. The function realizing means described below may be any circuit or device as long as it can realize the function, and part or all of the function can be realized by software. is there. Further, the function realizing means may be realized by a plurality of circuits, or the plurality of function realizing means may be realized by a single circuit.

The reception level measuring circuit according to the present invention detects a plurality of desired wave components, a plurality of interference wave components, and a plurality of frequency error vectors from the reception signal orthogonally detected by the desired wave / interference wave detecting means, The frequency error correction value acquisition means stores a correction value corresponding to the frequency error in advance, and the plurality of frequency error vectors detected by the desired wave / interference wave detection means are added and averaged to correspond to the unit-converted frequency error. Since the correction value is acquired, the frequency error correction means adds a plurality of desired wave components detected by the desired wave / interference wave detection means, and the desired wave component is corrected using the correction value, the transmitter / receiver is equipped with the correction value. It is possible to improve the measurement accuracy of the desired wave reception level by correcting the phase rotation caused by the frequency error of the oscillator.

Further, the reception level measuring circuit of the present invention is the desired wave power to interference wave power ratio measuring means, and obtains the desired wave power to interference wave power ratio from the interference wave reception level and the desired wave power level to obtain the desired wave power to interference wave power ratio. When the detected electric field strength exceeds a specific value in the correction with the specific value as a reference by the wave level correction means, and the desired wave power to the interference wave power ratio is greater than zero, the desired wave power is Correction to add the level of the detected electric field strength to the level of, and if the desired wave power to interference wave power ratio is less than or equal to zero, the correction to add the level of the detected electric field strength to the level of the desired wave power Since it is not performed, it is possible to improve the measurement accuracy of the desired wave component by avoiding improper correction when the desired wave does not exist.

The correspondence between each unit in the embodiment of the present invention and each unit in FIG. 1 is as follows. The received signal electric field strength detecting unit is an RSSI detecting unit 1, an A / D unit 2, an RSSI averaging unit 3 , Which corresponds to the voltage / dB conversion unit 4, and the quadrature detection means,
Corresponding to the AGC unit 5, the quadrature detection unit 6, the oscillator 7, and the A / D unit 8, the desired wave / interference wave detecting means is the desired wave / interference wave detecting units 9-1, 9-2, ... 9-N. Correspondingly, the frequency error correction value acquisition means is an adder 50, a frequency error averaging unit 51, an arctangent calculation unit 52, and a frequency error correction table 53.
The frequency error correction means corresponds to the adder 10, the pilot gain correction section 41, and the frequency error correction section 42, and the desired wave component power conversion means corresponds to the desired wave component power conversion section 1.
1 corresponds to the dB conversion unit 15, the interference wave component averaging unit corresponds to the interference wave component averaging unit 13 and the dB conversion unit 15, and the desired wave level correction unit corresponds to the desired wave level correction unit 12.
The interference wave level correcting means corresponds to the interference wave level correcting section 14, and the desired wave power to interference wave power ratio measuring means corresponds to the SIR measuring section 43.

First, the configuration of the reception level measuring circuit according to the present invention will be described with reference to FIG. FIG. 1 is a configuration block diagram of a reception level measuring circuit according to the present invention. still,
Parts having the same configuration as in FIG. 6 will be described with the same reference numerals.

The reception level measuring circuit of the present invention is similar to the conventional reception level measuring circuit in that the RSSI detecting section 1, the A / D converting section 2, the RSSI averaging section 3 and the voltage / dB converting section are provided. 4 and further, as a characteristic part of the present invention, an AGC unit 5, a quadrature detection unit 6, an oscillator 7, and
A / D unit 8, desired wave / interference wave detection unit 9, adder 10, pilot gain correction unit 41, frequency error correction unit 42, desired wave component power conversion unit 11, and dB conversion unit 15, a desired wave level correction unit 12, an interference component averaging unit 13, an interference wave level correction unit 14, and an SIR measurement unit 43.
An adder 50, a frequency error averaging unit 51, an arctangent calculation unit 52, and a frequency error correction table 5
3 and 3 are provided.

Next, each part of the apparatus will be specifically described. The RSSI detection part 1, the A / D conversion part 2, and the RSSI, which are components for detecting the radio part RSSI as in the conventional case.
The operations of the averaging unit 3 and the voltage / dB converting unit 4 are completely the same as those of the conventional one, so that the description thereof will be omitted and the characteristic part of the present invention will be specifically described.

The AGC section 5 has an automatic gain control (Automatic Gain Control).
Gain control (AGC) is performed, and the RSSI voltage detected by the RSSI detector 1 is used to amplify (or attenuate) the received power so as to be constant. The quadrature detection unit 6 demodulates the received signal in the radio frequency band and down-converts it into the in-phase and quadrature components of the baseband. The oscillator 7 outputs a carrier wave to the quadrature detection unit 6. The A / D unit 8 converts the analog baseband received signal down-converted by the quadrature detection unit 6 into a digital value.

The desired wave / interference wave detector 9 detects a desired wave component, an interference wave component, and a frequency error vector from the digitally converted baseband received signal, and a plurality of them are provided for each spread code. The DC-CDMA system is used to separate multipaths and detect a desired wave component, an interference wave component, and a frequency error vector for each path. The internal details will be described later.

The adder 50 adds the frequency error vectors from the desired wave / interference wave detectors 9 and synthesizes them. The frequency error averaging unit 51 averages the frequency error vector after addition. This is because the frequency error vector from each desired wave / interference wave detection unit 9 is the amount of phase rotation in one symbol time and includes the amount of phase rotation due to factors such as fading. This is for eliminating the phase rotation component due to fading by averaging the time and detecting it as the amount of phase rotation due to a fixed frequency error.

Arctangent operation unit (in the figure, arctan
The calculation unit) 52 adds ar to the frequency error vector after averaging.
Ctan calculation is performed to perform unit conversion into a frequency error (Hz). Specifically, arctan calculation is performed on the frequency error vector after averaging to obtain Δθ, and the frequency error (Hz) is further obtained from the one symbol time length, and unit conversion is performed. The frequency error correction table 53 is provided with a correction table in which correction values corresponding to frequency errors are stored in a table format, and the frequency error (H
z) as an input, and the corresponding correction value is output. The details of the correction table will be described later.

The adder 10 adds the desired wave components output from the desired wave / interference wave detecting section 9 and combines them. The pilot gain correction unit 41 corrects the offset of the pilot symbol portion added on the transmission side. That is, on the transmitting side, in consideration of the case where a power offset is added to the power of the data symbol portion in the pilot symbol portion (pilot gain) for transmission, the correction for this pilot gain is performed. For example, when the pilot symbol is transmitted with a power of 1/2 of the data symbol, the pilot gain correction unit 41 corrects the pilot gain by multiplying the combined desired wave component by √2. There is. The frequency error correction unit 42 corrects the frequency error of the desired wave component for which the addition and pilot gain have been corrected, using the frequency error correction value output from the frequency error correction table 53. The desired wave component power conversion unit 11 powers the desired wave component after frequency error correction.

The interference component averaging unit 13 has a plurality of desired waves /
The interference wave components from the interference wave detector 9 are averaged. The dB conversion unit 15 converts the desired wave component power output from the desired wave component power conversion unit 11 and the interference wave component power output from the interference component averaging unit 13 into dB.

The SIR measuring section 43 has a dB conversion section 15 with d
B-converted desired wave component power, interference wave component power to desired wave power to interference wave power ratio (Signal-to-Interference Rati
o: SIR).

The desired wave level correction unit 12 has the averaged RSSI that has been dB converted by the voltage / dB conversion unit 4, and
The spreading factor of the signal spread by spreading modulation on the transmitting side,
The fixed correction value for correcting the desired wave component power measured in the receiver to the absolute power value and the SIR value measured in the SIR measurement unit 43 are input, and the dB conversion unit 15
The power of the desired wave component output from is corrected, and the desired wave reception level is output. Details of the correction will be described later.

The interference wave level correction unit 14 has an averaged RSSI that has been dB converted by the voltage / dB conversion unit 4, and
The spreading factor of the signal spread by spreading modulation on the transmitting side,
The fixed correction value for correcting the desired wave component power measured in the receiver to the absolute power value and the SIR value measured in the SIR measurement unit 43 are input, and the dB conversion unit 15
The power of the interference wave component output from is corrected, and the reception level of the interference wave is output. Details of the correction will be described later.

Next, the internal configuration of the desired wave / interference wave detecting section 9 of the reception level measuring circuit of the present invention will be described with reference to FIG. FIG. 2 is a block diagram showing the internal configuration of the desired wave / interference wave detection unit 9 of the present invention. As shown in FIG. 2, the inside of the desired wave / interference wave detection unit 9 of the present invention includes a code generation unit 21, a despreading unit 22, a digital AGC unit 23,
Reference pilot symbol generator 25 and complex multiplier 2
6, a desired wave component averaging unit 27, an adder 28, a vector / scalar conversion unit 30, and an interference wave component power conversion unit 31.
, An exponentially weighted averaging unit 32, and a delay device (De
lay) 34 and a complex multiplier 35.

Each section inside the desired wave / interference wave detecting section 9 will be described. The code generation unit 21 generates a spreading code for reference, and different spreading codes are generated by the desired wave / interference wave detection units 9-1 to 9-N. The despreading unit 22 uses the A / D
The baseband received signal output from the unit 8 and the reference spreading code output from the code generation unit 21 are subjected to correlation calculation and despread.

The digital AGC section 23 shifts up the despread signal according to the spreading factor on the transmitting side. For example, assuming that the amplitude of the signal before despreading is A, the relationship between the amplitude after despreading and the spreading factor on the transmission side is ideally as shown in [Table 1].

[0031]

[Table 1]

As shown in [Table 1], the amplitude after despreading varies depending on the spreading factor. The lower the spreading factor, the smaller the amplitude after despreading, that is, the smaller the number of bits of the signal. If it is assumed that the processing in the subsequent stage is handled by fixed-point arithmetic, the reduction in the number of bits will cause deterioration of characteristics.
Therefore, in the digital AGC unit 23, it is possible to prevent the deterioration due to the decrease in the number of operation bits by performing shift-up according to the spreading rate so that the number of bits after despreading becomes constant.

The reference pilot symbol generator 25
A reference pilot symbol for obtaining an amplitude / phase variation amount described later is generated. The complex multiplier 26 is
The desired signal component vector is obtained by performing complex conjugate multiplication of the received signal after digital AGC and the reference pilot symbol to obtain the amplitude / phase variation amount.

The desired wave component averaging unit 27 includes a complex multiplier 2
The desired wave component vector from 6 is averaged.
The vector / scalar conversion unit 30 converts the desired wave component vector into a scalar.

The adder 28 calculates the difference between the desired wave component vector after averaging, which is the output of the desired wave component averaging unit 27, and the desired wave component vector before averaging, and sets it as the interference wave component vector. is there. The interference wave component power conversion unit 31 obtains the power of the interference wave component vector, and further averages a predetermined number of pilot symbols. The exponentially weighted averaging unit 32 exponentially weights and averages the electrified interference wave component over a long section.

The delay device (Delay in the figure) 34 delays the input signal by one symbol time. The complex multiplier 35 obtains a phase rotation amount in one symbol time as a frequency error vector by performing complex multiplication of the amplitude phase variation amount in a certain symbol and the amplitude phase variation amount in the preceding symbol.

Next, the operation of the reception level measuring circuit of the present invention will be described with reference to FIGS. In the reception level measuring circuit of the present invention, the reception signal of the radio frequency band input to the receiver is input to the RSSI detection unit 1 as in the conventional case, RSSI is detected and output as an analog voltage value, and A The digital value is converted by the / D conversion unit 2 and RS
The SI averaging unit 3 performs a predetermined averaging to obtain the voltage /
The measurement result of the reception level of the radio signal which is converted into the dB value by the dB conversion unit 4 and is input to the receiver is the RSSI dB.
It is output as a value.

On the other hand, the received signal of the input radio frequency band device is controlled in gain by the AGC section 5 using the RSSI voltage detected by the RSSI detection section 1 so that the received power becomes constant. Controlled. Further, in the quadrature detection unit 6, the carrier wave from the oscillator 7 is down-converted into the in-phase and quadrature components of the baseband. The down-converted baseband received signal is sent to the A / D unit 8
Is converted into a digital signal by and input to a plurality of desired wave / interference wave detecting sections 9 in parallel.

Here, the operation inside each desired wave / interference wave detecting section 9 will be described. Inside each desired wave / interference wave detection unit 9, the input baseband digital received signal is input to the despreading unit 22 and correlation calculation with the reference spreading code output from each code generating unit 21 is performed. Is performed and despreading is performed, and the received symbols after despreading are input to the digital AGC unit 23.

Then, in the digital AGC section 23, the signal after despreading is shifted up according to the spreading factor in the spreading modulation on the transmitting side to have a constant amplitude, and the digital AGC unit 23
The pilot symbol portion of the subsequent received symbol is subjected to complex conjugate multiplication in the complex multiplier 26 with the reference pilot symbol output from the reference pilot symbol generation unit 25, and the calculation result is the amplitude / phase variation amount, that is, The signal is output as a desired wave component vector, the desired wave component averaging unit 27 averages a predetermined number of pilot symbols, and the vector / scalar conversion unit 30 calculates and outputs the magnitude (scalar). It

Further, the difference between the desired wave component vector before averaging output from the complex multiplier 26 and the desired wave component vector after averaging output from the desired wave component averaging unit 27 is calculated by the adder 28. This becomes the interference wave component vector, the interference wave component powering unit 31 performs powering and averaging for a predetermined number of pilot symbols, and further, the exponential weighting averaging unit 32 performs averaging over a long section. Is output.

Now, the desired wave component and the interference wave component will be described with reference to FIGS. FIG. 3 is a format diagram showing an example of a frame format, and FIG. 4 is an explanatory diagram showing how the desired wave component vectors are averaged. It is assumed that pilot symbols P1 to P4 are periodically inserted in the received signal as shown in FIG. If the desired wave component vectors in pilot symbols P1 to P4 are vector P1 to vector P4 shown in FIG. 4, the desired wave component vector after averaging becomes vector R shown in FIG.

Further, the desired wave component vector averaged by the desired wave component averaging unit 27 is expressed by a mathematical expression as shown in [Equation 1].

[0044]

[Equation 1]

When the vector / scalar conversion unit 30 further performs vector / scalar conversion on the desired wave component vector, its output S can be expressed by [Equation 2].

[0046]

[Equation 2]

On the other hand, the variance of the desired wave component vectors P1 to P4 before averaging with respect to the desired wave component vector R after averaging,
That is, the interference wave component I represented by the interference wave component vector
Is the output from the interference wave component powering unit 31, and is expressed by [Equation 3].

[0048]

[Equation 3]

Further, the interference wave components are averaged over a long section in the exponentially weighted averaging unit 32, and the desired wave component (S) and the interference wave component (I ) Can be asked.

On the other hand, in the signal received by the receiver,
The phase rotation caused by the frequency error between the transmitter oscillator and the receiver oscillator is included. To correct this, the amplitude / phase fluctuation amount (desired wave component vector) at a certain symbol output from the complex multiplier 26 and the delay unit 1
The difference between the amplitude and phase fluctuation amount (desired wave component vector) in the preceding symbol delayed by the symbol time is obtained by the complex multiplier 35, and the phase rotation amount in one symbol time is obtained as the frequency error vector. The above is an example of the operation of each desired wave interference wave detection unit 9.

In the DS-CDMA system, since multipaths can be separated by despreading, the separated delayed waves are respectively assigned to the desired wave / interference wave detecting section 9 so that desired paths for each path can be obtained. By obtaining the wave component (S) and the interference wave component (I), and synthesizing and averaging them, the desired wave level and the interference wave level can be obtained.

Next, the operation of obtaining the desired wave reception level and the interference wave reception level after combining and averaging from the desired wave component (S) and the interference wave component (I) from the plurality of desired wave / interference wave detection units 9 explain. Regarding the desired wave component (S), the desired wave component ([Equation 2]) detected by each desired wave / interference wave detection unit 9 is added by the adder 10 and the desired wave component of each path separated by this is added. The sum of the components is obtained, and the desired wave component after synthesis can be obtained.

As one of the features of the present invention, the synthesized desired wave component is transmitted by adding a power offset (pilot gain) to the power of the data symbol portion in the pilot symbol portion on the transmitting side. In consideration of the case, the pilot gain correction unit 41 corrects the pilot gain added on the transmission side.

As a second characteristic of the present invention, the correction of the frequency error is performed on the synthesized desired wave component after the correction of the pilot gain. In particular,
The frequency error vector output from each desired wave / interference wave detection unit 9 is added by the adder 50 to obtain the combined frequency error vector, and the frequency error averaging unit 51 further averages the long section. Then, the phase rotation component due to fading is erased and detected as a phase rotation amount due to a fixed frequency error.

Then, the arc tangent calculator 52 performs arctan calculation on the frequency error vector after averaging to obtain a frequency error (Hz), and the frequency error correction table 53 shows a correction value corresponding to the frequency error. Desired.

Here, the correction table provided in the frequency error correction table 53 will be described in detail.
First, consider an ideal state with no frequency error. If the desired wave component vector after averaging in the desired wave component averaging unit 27 is R, then R (1,0).

[0057] In contrast, the frequency error f, when the number of symbols N to be averaged, the desired signal component vector R _'i of the i-th symbol can be expressed by the following equation. R ′ _i = (I + jQ) × (Cos (2πft) + jSin (2πft)) ... (Equation 4)

Therefore, for example, the frequency error is 200 Hz.
Yes, number of averaged symbols is 4, symbol rate is 15 ksp
Assuming that there is no fluctuation in the amplitude direction when s, f = 200, t = N × (1/15000), I =
1 and Q = 0, the respective desired wave component vectors R ′ ₁ , R ′ ₂ , R ′ ₃ and R ′ ₄ are R ′ ₁ (1,0) R ′ ₂ (0.996493, 0.083678). ) R become _{'3 (0.985996,0.166769) R' 4} (0.968583,0.24869).

Therefore, the desired wave component vector R'after averaging the above four symbols becomes R '(0.987768, 0.124784) from [Equation 2], and its magnitude is | R' | = 0. 995619, which is 0.9956 when there is no frequency error.
It is 19 times larger. Therefore, in the correction table, a value for correcting the above value to a magnitude of 1, that is, a table correction value at 200 Hz = 1 / 0.9956
19 = 1.004401 can be associated as a correction value for a frequency error of 200 Hz.

In the form as described above, correction values are obtained in advance for a plurality of frequency errors and stored as a correction table. Then, the frequency error correction table 53 outputs a correction value corresponding to the frequency error from the arctangent calculation unit 52 to the frequency error correction unit 42.

Then, the correction value obtained by associating with the frequency error in the frequency error correction table 53 is output to the frequency error correction unit 42, and the frequency error correction unit 42 outputs the desired wave after combining from the pilot gain correction unit 41. The component vector is multiplied by the correction value for correction, and the desired wave component powering unit 11 further powers the desired wave component after correction.

On the other hand, with respect to the interference wave component (I), the interference wave component ([Equation 3]) for each path is further averaged by the interference component averaging unit 13. This utilizes the fact that the desired wave component is combined by so-called RAKE combining, which combines the paths separated by despreading, and the interference components are independent of each path, so that they are averaged and suppressed after combining. It is a thing.

The desired wave component power output from the desired wave component power conversion unit 11 and the interference wave component power output from the interference component averaging unit 13 are respectively converted into dB conversion units 15.
Is converted to dB. The desired wave power to interference wave power ratio (SIR) of the desired wave component power and the interference wave component power, which have been dB-converted, is obtained by the SIR measuring unit 43.

Next, the concept of the method of correcting the desired wave component and the interference wave component will be described with reference to FIG. FIG. 5 is an explanatory diagram schematically showing the relationship between a desired wave component for baseband detection and RSSI. As shown in FIG. 5, when the received electric field is close to the in-band noise level (area A in the figure), R of the radio section detected by the RSSI detection section 1 to the voltage / dB conversion section 4 is detected.
The SSI will not be detected correctly because it pulls the floor, and the wireless unit AGC will not be properly applied. On the other hand, the desired wave component in the baseband can be detected linearly in the area A.

On the other hand, in the area B in the figure, the radio unit R
Since the SSI can be correctly detected, the wireless section AGC is correctly applied, and thus the desired wave component in the baseband is saturated and cannot be correctly detected. Therefore, in the region A, the desired wave component detected in the base band is used by using the desired wave component detected in the base band and the RSSI detected by the radio section detected by the RSSI detection unit 1 to the voltage / dB conversion unit 4. Is used as it is, and in the region B, the RSSI of the radio section is added as a correction value to the desired wave component detected in the base band, so that appropriate reception level detection can be performed in the entire reception electric field region.

A specific method for realizing the above correction method will be described. First, the lower limit value of the RSSI of the wireless unit that can be detected by the RSSI detection unit 1 to the voltage / dB conversion unit 4 is stored in advance in the desired wave level correction unit 12 as an analog parameter. In FIG. 5, the RSSI curve is the area A
The value at the point of intersection with the boundary between the area B and the area B is the lower limit of RSSI. Then, the detected RSSI of the wireless unit is
When this lower limit value is reached and becomes lower than the lower limit value, the radio section RSSI
Do not correct by. That is, the desired wave level after correction = desired wave level before correction + (radio section detection RSSI-radio section detection RSSI lower limit) (Equation 5). With this (Equation 5), A
In the area where GC is not applied (area A in FIG. 5), since the reliability of the RSSI value is low, correction by RSSI is not performed,
In the area where AGC is correctly applied (area B in FIG. 5), RSS
Correction by I can be realized.

Further, the desired wave level correction unit 12 corrects the desired wave level for baseband detection to absolute power. This is the spreading gain obtained by spreading modulation on the transmitting side, and the digital AG of the desired wave / interference wave detection unit 9.
The absolute power value of the desired wave level to be obtained can be obtained by holding a fixed correction value for the C section 23 as a parameter, and adding this to the desired wave level after the correction by the radio section RSSI.

Here, an example of a fixed correction value for the digital AGC section 23 of the desired wave / interference wave detection section 9 will be described. Now, consider the case where there is no interference in the received wave received by the receiver, that is, the received power is all the desired wave. In this case, spreading gain is obtained by performing despreading in the baseband. That is, ideal desired wave level = radio section RSSI when interference does not occur (Equation 6). The desired wave level detected by the baseband with respect to this ideal desired wave level has a fixed offset depending on the format at the time of calculation and the implementation method. In order to absorb this offset, the difference between the ideal desired wave level and the measured desired wave level when a received signal with no interference is input is held as a fixed correction value parameter, and By adding the correction value, it is possible to restore the absolute power value.

Further, S of the desired wave level and the interference wave level
The IR relationship can be expressed by the following equation. SIR (dB) = desired wave level-interference wave level + spreading gain (Equation 7) Therefore, in the interference wave level correction unit 14, the relation of (Equation 7) is applied to the correction performed by the desired wave level correction unit 12. It is designed to be corrected to an absolute power value so that

Further, in the DS-CDMA system, since a plurality of transmitters / receivers perform communication using the same radio frequency band, not all signals input to the receiver are desired wave components, and interference occurs. It was mentioned in the prior art that the wave component is included. Therefore, in the correction in the desired wave level correction unit 12, when the received electric field is at a level equal to or higher than the in-band noise, the desired wave level is corrected by adding the RSSI detected by the radio unit to the reception level measurement result according to (Equation 5). Then, even if the desired wave does not exist in the received signal, the correction is applied, and even if the desired wave does not exist, the level is measured as if the desired wave exists. There is a fear.

Therefore, as a third feature of the present invention, S
Using SIR measured by the IR measurement unit 43, for example, S
By using the SIR value as the correction threshold value, the correction of (Equation 5) is not performed when the IR is equal to or less than “0 dB” and the correction is performed when the IR is greater than “0 dB”.
It is possible to prevent inappropriate correction when the desired wave does not exist.

The reception level measuring circuit described above can be realized by a DSP (Digital Signal Processor).

According to the reception level measuring circuit of the embodiment of the present invention, in the plurality of desired wave / interference wave detecting sections 9, multipaths are separated by despreading, and desired signals for each path are separated from the separated delay waves. The wave component and the interference wave component are detected, and the desired wave component detected by each desired wave / interference wave detector 9 is added by an adder 10
Since the interference wave component is averaged by the interference component averaging unit 13, the desired wave level and the interference wave level can be measured separately, and unnecessary interference wave components included in the received wave are removed. The effect is that the level of the desired wave component can be acquired as the reception level.

Further, according to the reception level measuring circuit of the present invention, the desired wave level correcting unit 12 sets the desired wave level obtained by combining the desired wave components detected by the desired wave / interference wave detecting units 9 in the desired wave level correcting unit 12. When the received electric field is below the in-band noise level, the desired wave level is used as it is. When the received electric field is above the in-band noise level, the received signal level is corrected by adding RSSI detected by the radio section to the received level measurement result. There is an effect that it is possible to realize a reception level measuring circuit capable of measuring a level lower than the in-band noise of the radio unit of the machine.

Further, according to the reception level measuring circuit of the present invention, when the reception level measurement result is obtained by correcting the desired wave level by adding the RSSI detected by the radio section at a level higher than the in-band noise as described above, The SIR measurement unit 43 calculates the desired wave power to interference wave power ratio (SIR) so that the desired signal does not have an undesired correction, and the desired wave level correction unit 12 calculates the SIR. Since it is determined whether or not the correction for adding the RSSI as the threshold value is performed, there is an effect that an inappropriate correction when the desired wave does not exist can be avoided and the measurement accuracy of the desired wave component can be improved.

Further, according to the receiving level measuring circuit of the present invention, in order to correct the phase rotation caused by the frequency error between the oscillator on the transmitting side and the oscillator on the receiving side, each desired wave / interference wave detecting section 9 , The amount of phase rotation between symbols is obtained as a frequency error vector, and the desired wave component vector is corrected by the frequency error correction unit 42 using the correction value corresponding to the frequency error stored in advance. There is an effect that can improve.

Further, according to the reception level measuring circuit of the present invention, the frequency error vector obtained by each desired wave / interference wave detecting section 9 includes the phase rotation amount due to factors such as fading. After the frequency error vectors from the desired wave / interference wave detection units 9 are combined with each other, the frequency error averaging unit 51 performs averaging over a long section, and the phase rotation component due to fading is erased and fixed. Since it is detected as a phase rotation amount due to a large frequency error, the correction accuracy of the frequency error is improved, and the measurement accuracy of the desired wave component can be improved.

Further, according to the reception level measuring circuit of the present invention, in order to correct the offset (pilot gain) of the pilot symbol portion added on the transmitting side, the pilot gain added on the transmitting side by the pilot gain correcting section 41. Since the desired wave component after combining is corrected according to the above, the desired wave reception level measured using the pilot symbol can be brought closer to the desired wave reception level of the data symbol, and the accuracy of the desired wave reception level can be improved. There is.

The reception level measuring circuit of the present invention is connected to C
By adopting the base station and the mobile station of the DMA wireless communication system, when the detected electric field strength becomes equal to or lower than a predetermined specific value (lower limit value of RSSI), the level of the desired wave power is received. If it is output as a level and the detected electric field strength exceeds a specific value, correction is performed by adding the detected electric field strength level to the desired wave power level and output as the desired wave reception level. Can be accurately measured over the entire received electric field, and the closed-loop control type transmission power control can be effectively performed. Specifically, it can be realized by installing a transceiver that includes the reception level measurement circuit of the present invention and uses the output from the reception level measurement circuit to control the transmission power in a base station or a mobile station.

In addition to the basic correction described above, it is possible to determine whether or not there is a desired wave when there is no desired wave, to correct the frequency error between the oscillator on the transmitting side and the oscillator on the receiving side, or to correct the pilot gain. By also performing the above, it is possible to improve the measurement accuracy of the desired wave reception level and the interference wave reception level, and to effectively perform the closed-loop control type transmission power control.

[0081]

According to the present invention, a plurality of desired wave components, a plurality of interference wave components, and a plurality of frequency error vectors are detected from the received signal quadrature detected by the desired wave / interference wave detecting means, and the frequency error is detected. A correction value corresponding to the frequency error is stored in advance in the correction value acquisition means, and a plurality of frequency error vectors detected by the desired wave / interference wave detection means are added and averaged to perform unit conversion. Is obtained, and the frequency error correction means adds a plurality of desired wave components detected by the desired wave / interference wave detection means, and uses the correction value to correct the desired wave component. There is an effect that the phase rotation due to the frequency error of the oscillator included in the machine is corrected to improve the measurement accuracy of the desired wave reception level.

Further, according to the present invention, the desired wave power to interference wave power ratio measuring means obtains the desired wave power to interference wave power ratio from the interference wave reception level and the desired wave power level to correct the desired wave level. When the detected electric field strength exceeds the specified value when the correction is performed with the specified value as the reference, the desired wave power level is set to the desired wave power level if the desired wave power to the interference wave power ratio is greater than zero. Correction is performed to add the detected electric field strength level, and if the desired wave power to interference wave power ratio is less than or equal to zero, no correction is made to add the detected electric field strength level to the desired wave power level. Since the reception level measurement circuit is used, there is an effect that the measurement accuracy of the desired wave component can be improved by avoiding inappropriate correction when the desired wave does not exist.

[Brief description of drawings]

FIG. 1 is a configuration block diagram of a reception level measuring circuit according to the present invention.

FIG. 2 is a block diagram showing an internal configuration of a desired wave / interference wave detection unit of the present invention.

FIG. 3 is a format diagram showing an example of a frame format.

FIG. 4 is an explanatory diagram showing a state of averaging desired wave component vectors.

FIG. 5 is an explanatory diagram schematically showing the relationship between a desired wave component for baseband detection and RSSI.

FIG. 6 is a block diagram showing a configuration example of a conventional reception level measuring circuit.

[Explanation of symbols]

1 ... RSSI detector, 2 ... A / D converter, 3 ... RS
SI averaging unit, 4 ... voltage / dB conversion unit, 5 ... AGC
Section, 6 ... Quadrature detection section, 7 ... Oscillator, 8 ... A / D
Section, 9 ... Desired wave / interference wave detection section, 10 ... Adder,
11 ... Desired wave component power conversion unit, 12 ... Desired wave level correction unit, 13 ... Interference component averaging unit, 14 ... Interference wave level correction unit, 15 ... dB conversion unit, 21 ... Code generation unit,
22 ... Despreading unit, 23 ... Digital AGC unit, 25
... Reference pilot symbol generation unit, 26 ... Complex multiplier, 27 ... Desired wave component averaging unit, 28 ... Adder,
30 ... Vector / scalar conversion unit, 31 ... Interference wave component power conversion unit, 32 ... Exponential weighted averaging unit, 34 ... Delay device, 35 ... Complex multiplier, 41 ... Pilot gain correction unit, 42 ... Frequency error correction unit, 43 ... SIR measurement unit, 50 ... Adder, 51 ... Frequency error averaging unit, 52 ... Arc tangent calculation unit, 53 ... Frequency error correction table

Claims (3)

[Claims] 1. A received signal electric field strength detection means for detecting electric field strength of a received signal, a quadrature detection means for quadrature detection of the received signal, a plurality of desired wave components and a plurality of interference waves from the quadrature detected reception signal. Desired wave / interference wave detecting means for detecting a component and a plurality of frequency error vectors, and a frequency in which a correction value corresponding to the frequency error is stored in advance, and the detected plurality of frequency error vectors are added, averaged and unit-converted. A frequency error correction value acquisition unit that acquires a correction value corresponding to an error; a frequency error correction unit that adds the plurality of detected desired wave components and corrects the desired wave component using the correction value; A desired wave component powering means for powering the desired wave component to obtain the level of the desired wave power, and if the detected electric field strength is equal to or lower than a predetermined specific value, the desired wave component Output the power level as the desired wave reception level, and if the detected electric field strength exceeds the specific value, perform a correction to add the detected electric field strength level to the desired wave power level, A reception level measuring circuit, comprising: a desired wave level correcting means for outputting as a desired wave reception level. 2. An interference wave component averaging means for averaging a plurality of interference wave components detected by a desired wave / interference wave detecting means to output an interference wave reception level, and interference from the interference wave component averaging means. Wave reception level,
A desired wave power to interference wave power ratio measuring means for obtaining the desired wave power to interference wave power ratio from the desired wave power level is provided, and the desired wave level correcting means detects when performing correction based on a specific value. If the desired electric field strength exceeds the specific value and the desired wave power to interference wave power ratio is greater than zero, a correction for adding the detected electric field strength level to the desired wave power level And when the desired wave power to interference wave power ratio is less than or equal to zero, it is a means for not performing correction for adding the detected electric field strength level to the desired wave power level. Claim 1
The received level measuring circuit described. 3. The desired wave / interference wave detecting means includes a code generating section for generating a reference spreading code, a digitally converted baseband received signal, and a reference code output from the code generating section. Perform correlation calculation,
A despreading section for despreading, a digital AGC section for shifting up the despread signal according to the spreading factor on the transmission side, a reference pilot symbol generation section for generating a reference pilot symbol, and the digital AGC section A complex multiplier of the reference signal and the reference pilot symbol to obtain an amplitude / phase variation amount and obtain a desired wave component vector; a delay device that delays the desired wave component vector by one symbol time; Complex multiplication of the desired wave component vector of the symbol and the desired wave component vector one symbol before from the delay unit to obtain the phase rotation amount in one symbol time, and output as a frequency error vector, A desired wave component averaging unit for averaging the desired wave vector, and the averaged desired wave vector An adder for obtaining a difference from the previous desired wave vector and outputting an interference wave component vector, and a vector for converting the desired wave component vector from the desired wave component averaging unit into a scalar and outputting it as a desired wave component
A scalar conversion unit, an interference wave component power conversion unit that obtains the power of the interference wave component vector from the adder, and an exponential weighted averaging that exponentially weights the powered interference wave component and outputs it as an interference wave component. The reception level measuring circuit according to claim 1 or 2, further comprising: