JP3709345B2 - Diversity receiver - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a diversity receiver, and in particular, receives 0-system and 1-system received radio frequency (RF) signals by a predetermined level and uses signals distributed from a common oscillating means to respectively use 0-system and 1-system intermediate frequencies. The present invention relates to a diversity receiver including a radio unit that converts (IF) signals to output.
[0002]
[Prior art]
FIG. 9 is a diagram for explaining a conventional diversity receiver. In FIG. 9A, a radio base station 100 having a cross-connect configuration having a conventional diversity receiver 110 is a high-frequency signal transmitted from mobile terminals existing in three sectors, sector 1, sector 2 and sector 3. Receive.
[0003]
9 (a) and 9 (b), the radio base station 100 includes a 0-system antenna 3a and a 1-system antenna 3b, which are two pairs of antennas for diversity reception of a high-frequency signal from the mobile terminal 2a existing in the sector 1. A 0-system antenna 3c and a 1-system antenna 3d, which are two pairs of antennas for diversity reception of a high-frequency signal from the mobile terminal 2b existing in the sector 2, and a high-frequency signal from a mobile terminal (not shown) existing in the sector 3 It has a 0-system antenna 3e and a 1-system antenna 3f, which are two pairs of antennas for diversity reception of signals.
[0004]
And the low noise amplification parts 4a-4f for obtaining a favorable receiving characteristic are respectively connected directly under the antennas 3a-3f. That is, the high frequency signal received by the antenna 3a is amplified by the low noise amplification unit 4a, the high frequency signal received by the antenna 3b is amplified by the low noise amplification unit 4b, and the high frequency signal received by the antenna 3c is amplified by the low noise amplification. The high frequency signal amplified by the unit 4c and received by the antenna 3d is amplified by the low noise amplification unit 4d, and the high frequency signal received by the antenna 3e is amplified by the low noise amplification unit 4e and received by the antenna 3f. Is amplified by the low noise amplification unit 4f.
[0005]
FIG. 10 is a diagram showing a configuration of diversity receiver 110 shown in FIG. 9, and the same parts as those in FIG. 9 are denoted by the same reference numerals. In FIG. 10, a low noise amplifier 4a and a low noise amplifier 4d are connected to the radio unit 120a of the diversity receiver 110. Although not shown in FIG. 10, the diversity receiver 110 further includes a radio unit 120b and a radio unit 120c having the same configuration as the radio unit 120a. The radio unit 120b includes a low noise amplification unit. The unit 4c and the low noise amplification unit 4f are connected, and the low noise amplification unit 4e and the low noise amplification unit 4b are connected to the wireless unit 120c.
[0006]
As described above, the diversity receiver 110 having a cross-connect configuration has a redundant configuration by connecting the antennas 3a to 3f of different sectors to the systems of the radio units 120a to 120c having two reception branches for diversity. There is no. In other words, different reception high-frequency signals of the 0-system and the 1-system are input to the radio units 120a to 120c.
[0007]
FIG. 11 is a diagram illustrating a configuration of the wireless unit 120a illustrated in FIG. 10, in which the system of the antenna 3a is the 0 system and the system of the antenna 3d is the 1 system. In FIG. 11, the radio unit 120a of the double superheterodyne system amplifies a high-frequency signal input from the low-noise amplifier 4a by a predetermined level and amplifies the high-frequency signal input from the low-noise amplifier 4d by a predetermined level. The amplifying unit 12b and the output of the amplifying unit 12a are used as inputs, the high frequency filter unit 13a for attenuating the frequency component outside the band of the radio channel of the mobile communication system to be applied, and the output of the amplifying unit 12b as inputs and applied mobile And a high frequency filter unit 13b for attenuating frequency components outside the band of the radio channel of the communication system.
[0008]
Further, the wireless unit 120a includes a synthesizer unit 14 that outputs a first local signal, a distribution unit 15 that distributes the first local signal to each system, and a high-frequency signal that is output from the high-frequency filter unit 13a as a first local signal. A mixer unit 16a that converts the frequency to the first intermediate frequency signal by using the first local signal and a mixer unit 16b that converts the frequency of the high frequency signal output from the high frequency filter unit 13b to the first intermediate frequency signal. ing.
[0009]
Still further, the radio unit 120a receives the output of the mixer unit 16a as an input, the intermediate frequency filter unit 17a that limits the band to the radio channel to be used, and the intermediate frequency filter 17a that receives the output of the mixer unit 16b and limits the band to the radio channel to be used. The frequency filter unit 17b, the synthesizer unit 18 that outputs the second local signal, the distribution unit 19 that distributes the second local signal to each system, and the first intermediate frequency signal that is the output of the intermediate frequency filter unit 17a The mixer unit 20a that converts the frequency to the second intermediate frequency signal using the local signal and the first intermediate frequency signal that is the output of the intermediate frequency filter unit 17b are converted to the second intermediate frequency signal using the second local signal. And a mixer unit 20b.
[0010]
Further, the radio unit 120a detects the signal level of the second intermediate frequency signal that is the output of the mixer unit 20a and outputs a detection voltage, and the signal of the second intermediate frequency signal that is the output of the mixer unit 20b. A detector 21b that detects the level and outputs a detection voltage, and obtains the signal level of the 0-system received signal received by the antenna 3a from the detection voltage from the detector 21a, and the antenna 3d from the detection voltage from the detector 21b. A reception level reporting unit 130 that obtains the signal level of the received signal of the 1-system received and reports the signal level to a host device (not shown) is provided.
[0011]
Hereinafter, in FIG. 9, the operation of the diversity receiver 110 will be described focusing on the radio unit 120a, assuming that the radio base station apparatus 100 receives high-frequency signals transmitted from the mobile terminals 2a and 2b, respectively.
[0012]
10 and 11, the signal level of the high-frequency signal from the mobile terminal 2a received by the 0-system antenna 3a of the radio base station apparatus 100 is −100 [dBm], and the signal level from the mobile terminal 2b received by the 1-system antenna 3d is When the signal level of the high-frequency signal is −95 [dBm], the 0-system low noise amplification unit 4a amplifies the high-frequency signal by 40 [dB] and outputs a −60 [dBm] high-frequency signal. Similarly, the 1-system low-noise amplifier 4d amplifies the high-frequency signal by 40 [dB] and outputs a high-frequency signal of −55 [dBm].
[0013]
The radio unit 120a of the diversity receiver 110 performs frequency conversion in two steps and performs a total of 40 [dB] amplification. As a result, the mixer unit 20a of the radio unit 120a outputs a second intermediate frequency signal of −20 [dBm], and the mixer unit 20b similarly outputs a second intermediate frequency signal of −15 [dBm].
[0014]
The detector 21a converts the second intermediate frequency signal from the mixer unit 20a into a detected voltage and outputs it. The detector 21b converts the second intermediate frequency signal from the mixer unit 20b into a detection voltage and outputs it. The reception level reporting unit 130 obtains the level of the 0-system reception signal received by the antenna 3a as -100 [dBm] from the detection voltage from the detector 21a, and similarly, based on the detection voltage from the detector 21b. The level of the 1-system received signal received by the antenna 3d is determined to be −95 [dBm], and these are reported to a host device (not shown).
[0015]
[Problems to be solved by the invention]
However, in the conventional diversity receiver 110, for example, a high-frequency signal input to the 0 system is input to the 1 system as noise via the mixer unit 16a → the distributing unit 15 → the mixer unit 16b. At this time, if the signal level of the high-frequency signal input to the 1 system is lower than the signal level of the high-frequency signal input to the 0 system, the high-frequency signal that wraps around from the 0 system affects as a noise component. There is a problem that the reception sensitivity of the receiver is degraded.
[0016]
This also increases the noise power in the reception band, which causes a problem of suppressing the system capacity.
[0017]
Further, in the conventional diversity receiver 110, when a failure such as a gain reduction occurs in the radio units 120a to 120c, the host device (not shown) determines the abnormality by stopping the call from the mobile terminal. In order to investigate the failure source, there is a problem that it takes time to recover the system.
[0018]
A first object of the present invention is to provide a diversity receiver capable of suppressing deterioration of reception sensitivity.
[0019]
A second object of the present invention is to provide a diversity receiver that does not reduce the capacity of the system.
[0020]
A third object of the present invention is to provide a diversity receiver that can immediately detect a failure of a radio unit.
[0021]
[Means for Solving the Problems]
  The diversity receiver of the present invention amplifies the received high-frequency (RF) signals of the 0-system and 1-system at a predetermined level, and uses the signals distributed from the common oscillation means to each of the intermediate frequencies of the 0-system and 1-system. (IF) A diversity receiver including a radio unit that converts and outputs a signal, wherein the first signal level calculation unit calculates the RF signal level of the 0-system and 1-system, and the 0-system and 1-system Based on the second signal level calculation means for calculating the IF signal level, the 0-system and 1-system RF signal levels, and the 0-system and 1-system IF signal levels,The RF signal level that goes from the 0 system to the 1 system or from the 1 system to the 0 system is reduced.Control means for controlling the RF signal levels of the 0-system and the 1-system.
[0022]
  Further, in the diversity receiver, the control means is based on the 0-system and 1-system RF signal levels and the 0-system and 1-system IF signal levels.The RF signal level that goes from the 0 system to the 1 system or from the 1 system to the 0 system is reduced.Change amount calculating means for calculating each change amount of the 0-system and 1-system RF signal levels, and level variable means for variably controlling the 0-system and 1-system RF signal levels corresponding to these change amounts; It is characterized by having.
[0023]
  Also, the diversity receiver of the present invention amplifies the received high frequency (RF) signals of the 0 system and 1 system by a predetermined level, and uses the signals distributed from the common oscillation means, respectively, for the 0 system and 1 system. A diversity receiver including a radio unit that converts to an intermediate frequency (IF) signal and outputs the first signal level calculating means for calculating the RF signal level of the 0-system and 1-system, and the 0-system and 1 Based on the second signal level calculation means for calculating the IF signal level of the system, the RF signal level of the 0 system and the 1 system, and the IF signal level of the 0 system and the 1 system, the 0 system and the 1 system Control means for controlling the RF signal level, wherein the control means is based on the 0-system and 1-system RF signal levels and the 0-system and 1-system IF signal levels. Calculate each amount of change in RF signal level Includes a change amount calculating means, and a level varying means for variably controlling the 0-system and 1-system RF signal level corresponding accordingly such variation,The change amount calculation means compares the 1-system RF ′ signal level, which is a value obtained by subtracting the gain in the radio unit from the 1-system IF signal level, and the 1-system RF signal level, and The absolute value of the difference between the 0-system RF signal level and the 1-system RF signal level is compared with a predetermined value, and the amount of attenuation, which is the amount of change in the 0-system RF signal level, according to these comparison results And the level varying means attenuates the zero-system RF signal in accordance with the amount of attenuation.
[0024]
Still further, in the diversity receiver, the change amount calculating means includes a zero-system RF ′ signal level that is a value obtained by subtracting a gain in the radio unit from the zero-system IF signal level and the zero-system IF signal level. An RF signal level is compared, the absolute value is compared with the predetermined value, an attenuation amount which is a change amount of the RF signal level of the first system is calculated according to the comparison result, and the level varying means Is characterized in that the first-system RF signal is attenuated in accordance with the attenuation amount.
[0025]
  Furthermore, in the diversity receiver, when the RF signal level of the 1st system is higher than the RF ′ signal level of the 1st system, the change amount calculating means outputs an alarm indicating this, When the RF signal level of the system is higher than the RF ′ signal level of the 0 system, an alarm indicating this is output.
  Also, the diversity receiver of the present invention amplifies the received high frequency (RF) signals of the 0 system and 1 system by a predetermined level, and uses the signals distributed from the common oscillation means, respectively, for the 0 system and 1 system. A diversity receiver including a radio unit that converts to an intermediate frequency (IF) signal and outputs the first signal level calculating means for calculating the RF signal level of the 0-system and 1-system, and the 0-system and 1 Based on the second signal level calculation means for calculating the IF signal level of the system, the RF signal level of the 0 system and the 1 system, and the IF signal level of the 0 system and the 1 system, the 0 system and the 1 system Control means for controlling the RF signal level, wherein the control means is based on the 0-system and 1-system RF signal levels and the 0-system and 1-system IF signal levels. Calculate each amount of change in RF signal level Change amount calculation means, and level variable means for variably controlling the 0-system and 1-system RF signal levels corresponding to the change amounts, and the change amount calculation means includes the 0-system IF signal. The 0-system RF ′ signal level, which is a value obtained by subtracting the gain in the radio unit from the level, is compared with the 0-system RF signal level, and the 0-system RF signal level and the 1-system RF signal are compared. The absolute value of the difference from the level is compared with a predetermined value, and an amplification amount that is a change amount of the 0-system RF signal level is calculated according to these comparison results, and the level variable means The 0-system RF signal is amplified according to the above.
[0026]
The operation of the present invention is as follows. The first signal level calculation means calculates the signal levels of the received 0-system and 1-system RF signals. The second signal level calculating means amplifies the 0-system and 1-system RF signals by a predetermined level and converts them into IF signals using a common signal, and outputs the 0-system and 1-system IF signals. The signal level is calculated. The control means controls the RF signal levels of the 0-system and 1-system based on these calculated signal levels. More specifically, the change amount calculation means of the control means controls the IF signal level of the 1-system. The 1-system RF ′ signal level obtained by subtracting the gain at the radio unit from the 1-system RF signal level is compared, and the absolute value of the difference between the 0-system RF signal level and the 1-system RF signal level is compared. And the predetermined value are compared, and the attenuation amount of the 0-system RF signal level is calculated according to these comparison results. The change amount calculating means compares the 0-system RF ′ signal level obtained by subtracting the gain in the radio unit from the 0-system IF signal level and the 0-system RF signal level, and compares the absolute value with the above-described absolute value. A predetermined value is compared, and the attenuation amount of the 1-system RF signal level is calculated according to these comparison results. The level varying means of the control means attenuates the 0-system RF signal according to the attenuation amount of the 0-system RF signal level, and attenuates the 1-system RF signal according to the attenuation amount of the 1-system RF signal level. Let Further, when the RF signal level of the 1 system is higher than the RF ′ signal level of the 1 system, the change amount calculating means outputs an alarm indicating this because the 1 system of the radio unit is out of order. When the RF signal level of the system is higher than the RF ′ signal level of the 0 system, the 0 system of the radio unit is out of order, so an alarm indicating this is output.
[0027]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram for explaining a diversity receiver 6 according to an embodiment of the present invention. In addition, the equivalent part is shown with the same code | symbol about all the drawings. In FIG. 1 (a), a radio base station 1 having a cross-connect configuration having a diversity receiver 6 according to this embodiment is transmitted from mobile terminals existing in three sectors, sector 1, sector 2 and sector 3. Receive high frequency signals.
[0028]
1 (a) and 1 (b), the radio base station 1 performs the 0-system antenna 3a and the 1-system antenna 3b for diversity reception of the high-frequency signal from the mobile terminal 2a existing in the sector 1, as in FIG. A 0-system antenna 3c and a 1-system antenna 3d for diversity reception of a high-frequency signal from a mobile terminal 2b existing in the sector 2, and a 0-receiver for high-frequency signal from a mobile terminal (not shown) existing in the sector 3 It has a system antenna 3e and a system 1 antenna 3f.
[0029]
And the low noise amplification parts 4a-4f for obtaining a favorable receiving characteristic are respectively connected directly under the antennas 3a-3f. This is also the same as in FIG.
[0030]
FIG. 2 is a diagram showing the configuration of the diversity receiver 6 shown in FIG. In FIG. 2, the diversity receiver 6 according to the present embodiment includes a radio unit 5a, a detection unit 7, variable attenuation units 8a and 8b, a reception level calculation unit 9, an attenuation amount calculation unit 10, and a control unit 11. have.
[0031]
The detection unit 7 detects the signal level of each high-frequency signal input from the low noise amplification units 4a and 4d and outputs a detection voltage. The variable attenuating unit 8a attenuates the high frequency signal from the low noise amplifying unit 4a according to the control voltage from the control unit 11, and the variable attenuating unit 8b receives the high frequency signal from the low noise amplifying unit 4d from the control unit 11. Attenuate according to the control voltage.
[0032]
The radio unit 5a converts the high-frequency signals output from the variable attenuating units 8a and 8b into second intermediate frequency signals, respectively, and outputs them to a host device (not shown), and a signal calculated based on the second intermediate frequency signals The level is output to the attenuation calculation unit 10 and the amount of attenuation of each of the variable attenuation units 8a and 8b notified from the attenuation calculation unit 10 is corrected to calculate the signal level.
[0033]
The reception level calculation unit 9 calculates the signal levels of the 0-system and 1-system high-frequency signals received by the antennas 3a and 3d based on the detection voltages from the detection unit 7, respectively. Hereinafter, the 0-system high-frequency signal level calculated by the reception level calculation unit 9 is referred to as a 0-system RF signal level, and the 1-system high-frequency signal level calculated by the reception level calculation unit 9 is referred to as a 1-system RF signal level. Call.
[0034]
The attenuation amount calculation unit 10 is based on the 0-system and 1-system RF signal levels calculated by the reception level calculation unit 9 and the signal level calculated by the radio unit 5a, and the attenuation required by the variable attenuation units 8a and 8b. Calculate the amount. The control unit 11 converts the attenuation amounts required by the variable attenuation units 8a and 8b from the attenuation amount calculation unit 10 into control voltages, respectively, and outputs them to the variable attenuation units 8a and 8b.
[0035]
A0 is the signal level of the 0-system high frequency signal received by the antenna 3a, that is, the 0-system RF signal level, and A1 is the signal level of the 1-system high-frequency signal received by the antenna 3d, that is, the 1-system RF signal level. The RF signal level, B0 is the signal level of the high-frequency signal that is the output of the low-noise amplification unit 4a, B1 is the signal level of the high-frequency signal that is the output of the low-noise amplification unit 4d, and C0 is the high-frequency signal that is the output of the variable attenuation unit 8a. , C1 is the signal level of the high-frequency signal that is the output of the variable attenuator 8b. D0 and D1 will be described later.
[0036]
Although not shown in FIG. 2, the diversity receiver 6 further includes a radio unit 5b and a radio unit 5c having the same configuration as the radio unit 5a. That is, the diversity receiver 6 includes a radio unit 5a, a detector unit 7, variable attenuation units 8a and 8b, a reception level calculation unit 9, an attenuation amount calculation unit 10, and a control unit 11 for the antennas 3a and 3d. If it is set as one set, it further has a similar set (including the radio unit 5b) for the antennas 3c and 3f, and a similar set (including the radio unit 5c) for the antennas 3e and 3b. It is.
[0037]
As described above, the diversity receiver 6 having a cross-connect configuration has a redundant configuration by connecting the antennas 3a to 3f of different sectors to the systems of the radio units 5a to 5c having two reception branches for diversity. There is no. In other words, different reception high-frequency signals of the 0-system and the 1-system are input to the radio units 5a to 5c.
[0038]
FIG. 3 is a diagram illustrating a configuration of the wireless unit 5a illustrated in FIG. 2, in which the system of the antenna 3a is the 0 system and the system of the antenna 3d is the 1 system. In FIG. 3, the radio unit 5a of the double superheterodyne system includes an amplifier unit 12a and 12b, a high frequency filter unit 13a and 13b, a synthesizer unit 14 and 18, a distribution unit 15 and 19, and a mixer unit 16a, 16b, 20a. And 20b, intermediate frequency filter sections 17a and 17b, and detectors 21a and 21b. Since these are the same as those in FIG.
[0039]
Further, the radio unit 5a is based on the detection voltages from the detectors 21a and 21b, and the signal levels of the second intermediate frequency signals of the 0 system and the 1 system, which are the outputs of the mixer units 20a and 20b (the output of the radio unit 5a). Further, the 0-system and 1-system obtained by subtracting the gain of the radio section 5a and the gain of the low-noise amplification section 4a or 4d from the calculated 0-system and 1-system intermediate frequency signal levels. It has a reception level reporting unit 22 that outputs the value to the attenuation amount calculating unit 10 and a host device (not shown).
[0040]
Hereinafter, the 0-system second intermediate frequency signal level calculated by the reception level reporting unit 22 is referred to as a 0-system IF signal level, and the 1-system second intermediate frequency signal level calculated by the reception level reporting unit 22 is set to 1. The value obtained by subtracting the gain of the radio unit 5a and the gain of the low noise amplifying unit 4a from the IF signal level of the 0 system in the reception level reporting unit 22 is called the 0 system RF 'signal. The value obtained by subtracting the gain of the radio unit 5a and the gain of the low noise amplification unit 4d from the IF signal level of the 1 system in the reception level reporting unit 22 is called the 1 system RF ′ signal level. Note that the 0-system RF 'signal level is equivalent to the 0-system RF signal level, and the 1-system RF' signal level is equivalent to the 1-system RF signal level.
[0041]
The reception level reporting unit 22 further corrects the amount of attenuation of each of the variable attenuation units 8a and 8b notified from the attenuation amount calculation unit 10 to obtain the RF ′ signal levels of the 0-system and the 1-system. System 1 and system 1 RF 'signal levels are reported to the attenuation calculation unit 10 and a host device (not shown).
D0 is the signal level of the second intermediate frequency signal that is the output of the mixer unit 20a, that is, the 0-system IF signal level, and D1 is the signal level of the second intermediate frequency signal that is the output of the mixer unit 20b, that is, 1 The IF signal level of the system, A0 ′ is the RF ′ signal level of the 0 system, and A1 ′ is the RF ′ signal level of the 1 system.
[0042]
FIG. 4 is a diagram showing the configuration of the detection unit 7 shown in FIG. In FIG. 4, the detection unit 7 outputs a high-frequency signal from the synthesizer unit 23 a and the synthesizer units 23 a and 23 b that output the first local signal in the same manner as the synthesizer unit 14 and the low-noise amplification unit 4 a in the same manner as the mixer unit 16 a. The mixer unit 24a converts the frequency to the first intermediate frequency signal using the first local signal, and the high frequency signal from the low noise amplifying unit 4d is used as the first local signal from the synthesizer unit 23b, similarly to the mixer unit 16b. And a mixer unit 24b for converting the frequency to the first intermediate frequency signal.
[0043]
Similarly to the intermediate frequency filter unit 17a, the detection unit 7 is similar to the intermediate frequency filter unit 25a that limits the band to the radio channel that uses the first intermediate frequency signal from the mixer unit 24a, and the intermediate frequency filter unit 17b. The signal level of the first intermediate frequency signal from the intermediate frequency filter unit 25a is the same as that of the detector 21a and the intermediate frequency filter unit 25b that limits the band to the radio channel that uses the first intermediate frequency signal from the mixer unit 24b. Like the detector 21b, a detector 26a that detects and outputs a detected voltage, and a detector 26b that detects the signal level of the first intermediate frequency signal from the intermediate frequency filter unit 25b and outputs the detected voltage are provided. Yes.
[0044]
Next, the operation of the diversity receiver 6 according to the embodiment of the present invention will be described with reference to the drawings. Hereinafter, in FIG. 1, the operation of the diversity receiver 6 will be described focusing on the radio unit 5a, assuming that the radio base station apparatus 1 receives high-frequency signals respectively transmitted from the mobile terminals 2a and 2b. FIG. 5 is a flowchart for explaining the operation of the diversity receiver 6 according to the embodiment of the present invention.
[0045]
1 to 5, the attenuation amount calculation unit 10 includes a 0-system RF signal level A0 [dBm] calculated by the reception level calculation unit 9 and a 1-system RF signal level A1 [dBm]. A0 ′ [dBm], which is the RF system signal level of 0 system, and A1 ′ [dBm], which is the RF level of the 1 system, calculated by the reception level reporting unit 22 of the radio unit 5a are input (steps). S1). When comparing the 0-system RF signal level A0 and the 0-system RF ′ signal level A0 ′, and when comparing the 1-system RF signal level A1 and the 1-system RF ′ signal level A1 ′, Considering the delay t [μsec] generated in the unit 5a, the 0-system RF signal level A0 and the 1-system RF signal level A1 are delayed by t [μsec] and compared.
[0046]
The attenuation amount calculation unit 10 compares the 0-system RF signal level A0 with the 0-system RF ′ signal level A0 ′ (step S2), and if A0 = A0 ′, the 1-system high-frequency signal in the wireless unit 5a. Is not sneaking into the 0 system (step S3), the attenuation amount calculation unit 10 outputs a control signal for setting the attenuation amount of the 1 system variable attenuation unit 8b to 0 [dB], the control unit 11 and the reception level reporting unit 22. (Step S4).
[0047]
In step S9, the attenuation amount of the variable attenuation unit 8b changes to 0 [dB]. In step S10, the reception level reporting unit 22 considers the attenuation amount 0 [dB], and the 1-system RF ′ signal level A1 ′. And the attenuation amount calculation unit 10 is notified of this.
[0048]
Similarly, the attenuation amount calculation unit 10 compares the 1-system RF signal level A1 with the 1-system RF ′ signal level A1 ′ (step S2), and if A1 = A1 ′, the 0-system in the wireless unit 5a. Therefore, the attenuation amount calculation unit 10 outputs a control signal for setting the attenuation amount of the variable attenuation unit 8a of the 0 system to 0 [dB] as the control unit 11 and the reception level. It outputs to the report part 22 (step S4).
[0049]
In step S9, the attenuation amount of the variable attenuation unit 8a changes to 0 [dB]. In step S10, the reception level reporting unit 22 considers the attenuation amount 0 [dB], and the 0-system RF ′ signal level A0 ′. And the attenuation amount calculation unit 10 is notified of this.
[0050]
In step S2, if A0> A0 ′, the gain of the 0 system in the wireless unit 5a is reduced, that is, a failure occurs (step S11), the attenuation amount calculation unit 10 generates a failure alarm indicating this. The data is output to a host device (not shown) via the reception level reporting unit 22 (step S12).
[0051]
Similarly, in step S2, if A1> A1 ′, the gain of the 1 system in the wireless unit 5a is reduced, that is, a failure has occurred (step S11), the attenuation calculation unit 10 indicates a failure alarm indicating this. Is output to a host device (not shown) via the reception level reporting unit 22 (step S12).
[0052]
In step S2, if A0 <A0 ′, the 1-system high-frequency signal wraps around the 0-system in the wireless unit 5a (step S5), the attenuation calculation unit 10 is a 1-system variable attenuation unit. The attenuation amount 8b is calculated (step S6). The attenuation amount calculation unit 10 obtains a difference (ratio) X [dB] (X [dB] = | A0−A1 |) between the 0-system RF signal level A0 and the 1-system RF signal level A1 and X [dB ] Is larger than the set value (predetermined value) P [dB], the amount of interference is (X-P) [dB]. Therefore, the amount of attenuation of the one-system variable attenuation unit 8b having a high signal level is set to (X-P ) [DB], the control signal is output to the control unit 11 and the reception level reporting unit 22 (step S7).
[0053]
Here, the set value P for calculating the attenuation amount is an absolute value of the signal level difference between the 0 system and the 1 system that does not deteriorate the reception sensitivity obtained from the design value of the isolation in the radio unit 5a. Specifically, for example, if the isolation between the 0-system and the 1-system in the wireless unit 5a is designed at 40 [dB], the level of the sneak signal that does not deteriorate the reception sensitivity by 0.1 [dB] or more. Needs to be 16 dB lower than the desired wave, the ratio of the signal levels of the high-frequency signals input between the 0-system and the 1-system of the radio unit 5a needs to be within 24 [dB]. Accordingly, the set value P in this case is 24 [dB].
[0054]
In step S9, the attenuation amount of the variable attenuation unit 8b changes to (X−P) [dB], and in step S10, the reception level reporting unit 22 considers the attenuation amount (X−P) [dB] and changes to 1. An RF ′ signal level A1 ′ of the system is calculated, and this is notified to the attenuation calculation unit 10.
[0055]
In step S6, when X [dB] is equal to or less than P [dB], there is no interference, and therefore the attenuation amount calculation unit 10 sets the attenuation amount of the 1-system variable attenuation unit 8b to 0 [dB] and sets the control signal. Is output to the control unit 11 and the reception level reporting unit 22 (step S8).
[0056]
In step S9, the attenuation amount of the variable attenuation unit 8b changes to 0 [dB]. In step S10, the reception level reporting unit 22 considers the attenuation amount 0 [dB], and the 1-system RF ′ signal level A1 ′. And the attenuation amount calculation unit 10 is notified of this.
[0057]
Similarly, in step S2, if A1 <A1 ′, the zero-system high-frequency signal wraps around the first system in the wireless unit 5a (step S5), the attenuation calculation unit 10 performs the 0-system variable attenuation. The attenuation amount of the unit 8a is calculated (step S6). The attenuation amount calculation unit 10 obtains a difference X [dB] between the 0-system RF signal level A0 and the 1-system RF signal level A1, and when X [dB] is larger than the set value P [dB], the interference amount is Since (XP) [dB], the attenuation amount of the 0-system variable attenuation unit 8a having a high signal level is set to (XP) [dB], and the control signal is sent to the control unit 11 and the reception level reporting unit 22. Output (step S7).
[0058]
In step S9, the attenuation amount of the variable attenuation unit 8a changes to (X−P) [dB], and in step S10, the reception level reporting unit 22 considers the attenuation amount (X−P) [dB] to 0. The system RF ′ signal level A 0 ′ is calculated, and this is notified to the attenuation calculation unit 10.
[0059]
In step S6, when X [dB] is equal to or smaller than P [dB], there is no interference, and therefore the attenuation amount calculation unit 10 sets the attenuation amount of the 0-system variable attenuation unit 8a to 0 [dB] and controls the control signal. Is output to the control unit 11 and the reception level reporting unit 22 (step S8).
[0060]
In step S9, the attenuation amount of the variable attenuation unit 8a changes to 0 [dB]. In step S10, the reception level reporting unit 22 considers the attenuation amount 0 [dB], and the 0-system RF ′ signal level A0 ′. And the attenuation amount calculation unit 10 is notified of this.
[0061]
Hereinafter, the operation of the diversity receiver 6 according to the embodiment of the present invention will be described more specifically. 1 to 5, as described above, it is assumed that the isolation between the 0-system and the 1-system in the wireless unit 5a is designed at 40 [dB], and therefore, the set value P = 24 [dB].
[0062]
The signal level of the high-frequency signal received by the 0-system antenna 3a of the diversity receiver 6 is A0 = -100 [dBm], and the signal level of the high-frequency signal received by the 1-system antenna 3d is A1 = -95 [dBm]. In this case, the 0-system low noise amplification unit 4a amplifies the high-frequency signal by 40 [dB] and outputs a high-frequency signal of B0 = −60 [dBm]. The 1-system low-noise amplifier 4b amplifies the high-frequency signal by 40 [dB] and outputs a high-frequency signal of B1 = −55 [dBm].
[0063]
The detector 7 converts the frequency to the first intermediate frequency signal, limits the band to the radio channel to be used, and the detector 26a outputs the detection voltage 1.5 [V] from the characteristics of FIG. FIG. 6 is a diagram showing the characteristics of the detectors 21a, 21b, 26a and 26b.
[0064]
The reception level calculation unit 9 uses the known characteristics of FIG. 6 and the gains of the antenna 3a to the low noise amplification unit 4a so that the 0-system RF signal level that is the signal level of the high-frequency signal received by the 0-system antenna 3a is A0. = -100 [dBm] is obtained and notified to the attenuation amount calculation unit 10 (step S1). On the other hand, since the attenuation amount of the variable attenuation unit 8a is 0 [dB] as an initial setting, C0 = B0 = −60 [dBm] is input to the wireless unit 5a as it is.
[0065]
The radio unit 5a performs frequency conversion in two steps and performs a total of 40 [dB] amplification. As a result, the radio unit 5a outputs the second intermediate frequency signal of D0 = −20 [dBm] to the detector 21a and a host device (not shown) in which signal processing is performed. The detector 21a outputs a detection voltage 2.8 [V] with respect to the second intermediate frequency signal based on the characteristics shown in FIG.
[0066]
The reception level reporting unit 22 obtains D0 = −20 [dBm] from the known characteristics of FIG. 6, and subtracts the gain of the antenna 3a to the radio unit 5a from D0 = −20 [dBm], so that the 0-system RF is obtained. “Signal level A0” = − 100 [dBm] is obtained and notified to the attenuation calculation unit 10 and a host device (not shown) (step S1).
[0067]
The attenuation amount calculation unit 10 compares the 0-system RF signal level A0 calculated by the reception level calculation unit 9 with the 0-system RF ′ signal level A0 ′ calculated by the reception level reporting unit 22 (−100 [ dBm]) = (− 100 [dBm]) (steps S2 and S3), a control signal with an attenuation of 0 [dB] is output (step S4).
[0068]
The control unit 11 outputs the control voltage 0 [V] to the 1-system variable attenuation unit 8b based on the control signal and the characteristics shown in FIG. As a result, the attenuation amount of the 1-system variable attenuation unit 8b is 0 [dB] (step S9). FIG. 7 is a diagram showing the characteristics of the variable attenuation sections 8a and 8b.
[0069]
Also, the reception level reporting unit 22 that has received the control signal with the attenuation of 0 [dB] has the attenuation of 0 [dB], so that A0 ′ = − 100 [dBm] is used as it is. Report to the device (step S10). The system 1 that receives the high frequency signal of A1 = −95 [dBm] is also operated in the same manner as the system 0, the attenuation of the variable attenuating unit 8a is 0 [dB], and the reception level report value is A1 ′ = −. 95 [dBm].
[0070]
Next, the signal level of the high-frequency signal received by the 0-system antenna 3a remains A0 = -100 [dBm], and the signal level of the high-frequency signal received by the 1-system antenna 3d is A1 = -95 [dBm]. When A1 = −60 [dBm], the same operation as described above is performed, and the reception level calculation unit 9 obtains the 0-system RF signal level as A0 = −100 [dBm], and the attenuation calculation unit 10 Output (step S1).
[0071]
On the other hand, in the radio unit 5a, the input signal level to the 1 system of the radio unit 5a is C1 = −20 [dBm], and the input signal level to the 0 system of the radio unit 5a is C0 = −60 [dBm]. Therefore, the 1-system high-frequency signal of A1 = −60 [dBm] wraps around to the 0-system. Therefore, interference occurs and the mixer unit 20a of the radio unit 5a outputs a second intermediate frequency signal of D0 = −17 [dBm].
[0072]
Accordingly, the reception level reporting unit 22 outputs the 0-system RF ′ signal level A0 ′ = − 97 [dBm] to the attenuation amount calculation unit 10 (step S1). The attenuation amount calculation unit 10 compares the 0-system RF signal level A0 calculated by the reception level calculation unit 9 with the 0-system RF ′ signal level A0 ′ calculated by the reception level reporting unit 22 (step S2). Since (−100 [dBm]) <(− 97 [dBm]), the process proceeds to calculation of the attenuation amount of the variable attenuation unit 8b (steps S5 and S6).
[0073]
The attenuation amount calculation unit 10 obtains X = 40 [dB] from the 0-system RF signal level A0 = −100 [dBm] and the 1-system RF signal level A1 = −60 [dBm]. Here, as described above, the setting value P = 24 [dB]. Accordingly, since the ratio X = 40 [dB] of the input signal levels of both systems is larger than P = 24 [dB], the attenuation amount calculation unit 10 has a high signal level of the 1 system variable attenuation unit 8b. A control signal with an attenuation amount X−P = 40−24 = 16 [dB] is output (step S7).
[0074]
When the control unit 11 outputs the control voltage 3.3 [V], the attenuation amount of the variable attenuation unit 8b changes to 16 [dB], and the input signal level to the 1 system of the wireless unit 5a is C1. = −36 [dBm] (Step S9). Since this signal level does not affect the 0 system, the signal level of the second intermediate frequency signal that is the output of the 0 system mixer section 20a is D0 = −20 [dBm]. Also, the reception level reporting unit 22 performs 16 [dB] correction when calculating the 1-system RF ′ signal level A1 ′ and reports it to the attenuation calculation unit 10 and a host device (not shown) (step S10). .
[0075]
Next, the signal level of the high-frequency signal received by the 0-system antenna 3a of the diversity receiver is A0 = -100 [dBm], and the signal level of the high-frequency signal received by the 1-system antenna 3d is A1 = -95 [dBm]. When the 0 system of the radio unit 5a fails and the gain of the 0 system of the radio unit 5a becomes 0 [dB], the same operation as described above is performed, and the reception level calculation unit 9 Is obtained as A0 = −100 [dBm] and notified to the attenuation calculation unit 10 (step S1).
[0076]
On the other hand, since the gain of the 0 system of the wireless unit 5a is 0 [dB], the mixer unit 20a outputs the second intermediate frequency signal of D0 = C0 = −60 [dBm]. The reception level reporting unit 22 calculates the RF-signal level A0 ′ of the 0 system taking into account the original gain of 40 [dB] of the 0 system of the radio unit 5a, so A0 ′ = − 140 [dBm]. And notifies the attenuation amount calculation unit 10 (step S1).
[0077]
The attenuation amount calculation unit 10 compares the 0-system RF signal level A0 calculated by the reception level calculation unit 9 with the 0-system RF ′ signal level A0 ′ calculated by the reception level reporting unit 22 (step S2). Since (−100 [dBm])> (− 140 [dBm]), a failure alarm indicating a failure of the 0 system of the wireless unit 5a is output to a host device (not shown) via the reception level reporting unit 22 ( Steps S11 and S12).
[0078]
Thus, in the diversity receiver 6 according to the embodiment of the present invention, by monitoring the high-frequency signals of both systems in the previous stage of the radio unit 5a and the second intermediate frequency signals of both systems in the subsequent stage of the radio unit 5a, It is possible to calculate the amount of interference caused by the high-frequency high-frequency signal of one system that wraps around the other system, and this interference amount is attenuated as the attenuation of the high-frequency high-frequency signal of the system that causes the interference. Can be prevented, and increase in noise power can be suppressed to prevent deterioration of reception sensitivity.
[0079]
In the diversity receiver 6 according to the present embodiment, the calculated amount of interference is used as the amount of attenuation of the signal of the system that is the cause of the interference, so that the amount of attenuation in the variable attenuation unit of the system can be minimized. In addition, it is possible to suppress degradation of the reception sensitivity of the system.
[0080]
Furthermore, since the diversity receiver 6 according to the present embodiment can prevent interference as described above, it is possible to prevent suppression of system capacity caused by an increase in noise power due to interference.
[0081]
Further, in the diversity receiver 6 according to the present embodiment, by comparing the 0-system RF signal level with the 0-system RF ′ signal level, the 1-system RF signal level and the 1-system RF ′ signal level are also compared. Since the decrease in the gain of each system of the wireless unit 5a is monitored, a failure of each system of the wireless unit 5a can be immediately detected.
[0082]
In this embodiment, the reception level calculation unit 9 calculates the 0-system RF signal level A0 and the 1-system RF signal level A1 based on the detection voltage from the detection unit 7, but the low-noise amplification unit The output signal level B0 of 4a and the output signal level B1 of the low noise amplification unit 4d may be calculated, and these B0 and B1 may be notified to the attenuation amount calculation unit 10.
[0083]
At this time, the reception level reporting unit 22 also has a signal level B0 ′ equivalent to the output signal level B0 of the low noise amplifying unit 4a and the output signal level B1 of the low noise amplifying unit 4d based on the detection voltages from the detectors 21a and 21b. The signal level B1 ′ equivalent to the above is calculated, and B0 ′ and B1 ′ are notified to the attenuation amount calculation unit 10.
[0084]
Then, the attenuation amount calculation unit 10 compares B0 and B0 ′ (compares B1 and B1 ′) and compares it with the set value P as X = | B0−B1 |. Similar effects can be obtained.
[0085]
Next, another embodiment of the present invention will be described with reference to the drawings. FIG. 8 is a diagram illustrating a configuration of a diversity receiver according to another embodiment of the present invention. In FIG. 8, what is different from FIG. 2 is an amplification amount calculation unit 27, a control unit 28, and variable amplification units 29a and 29b, and the others are the same.
[0086]
The amplification amount calculation unit 27 includes the 0-system RF signal level and the 1-system RF signal level calculated by the reception level calculation unit 9 and the 0-system RF ′ signal level calculated by the reception level reporting unit 22 of the wireless unit 5a. And the variable amplification units 29a and 29b calculate the amplification amount required based on the RF ′ signal level of the first system. The control unit 28 converts the amplification amounts required by the variable amplification units 29a and 29b from the amplification amount calculation unit 27 into control voltages, and outputs them to the variable amplification units 29a and 29b.
[0087]
The variable amplification unit 29a amplifies the high frequency signal from the low noise amplification unit 4a according to the control voltage from the control unit 28, and the variable amplification unit 29b receives the high frequency signal from the low noise amplification unit 4d from the control unit 28. Amplify according to the control voltage.
[0088]
The operation of the diversity receiver 6 according to another embodiment of the present invention will be described with reference to the drawings. In FIG. 5, “attenuation amount” is read as “amplification amount”, “variable attenuation unit 8b (8a)” in step S9 is read as “variable amplification unit 29a (29b)”, and “attenuation” in step S10. It is assumed that “amount calculation unit 10” is read as “amplification amount calculation unit 27”.
[0089]
8, 3, and 5, the amplification amount calculation unit 27 includes a 0-system RF signal level A0 [dBm] calculated by the reception level calculation unit 9 and a 1-system RF signal level A1 [dBm]. And A0 ′ [dBm], which is the 0-system RF ′ signal level calculated by the reception level reporting section 22 of the wireless unit 5a, and A1 ′ [dBm], which is the 1-system RF ′ signal level, are input. (Step S1).
[0090]
The amplification amount calculation unit 27 compares the 0-system RF signal level A0 with the 0-system RF ′ signal level A0 ′ (step S2), and when A0 = A0 ′, the 1-system high-frequency signal in the wireless unit 5a. Is not sneaking into the 0 system (step S3), the amplification amount calculation unit 27 outputs a control signal for setting the amplification amount of the 0 system variable amplification unit 29a to 0 [dB] by the control unit 28 and the reception level reporting unit 22. (Step S4). Thereafter, the process proceeds to steps S9 and S10. The case of A1 = A1 'is also the same as described above, and the description thereof is omitted. However, in this case, the amplification amount of the 1-system variable amplification unit 29b is 0 [dB].
[0091]
In step S2, if A0> A0 ′, the gain of the 0 system in the wireless unit 5a is reduced, that is, a failure occurs (step S11), the amplification amount calculation unit 27 generates a failure alarm indicating this. The data is output to a host device (not shown) via the reception level reporting unit 22 (step S12). The case of A1> A1 'is also the same as described above, and the description thereof is omitted. However, in this case, the failure alarm that is output is an alarm that indicates a failure of the first system in the wireless unit 5a.
[0092]
In step S2, if A0 <A0 ′, the 1-system high frequency signal wraps around the 0-system in the wireless unit 5a (step S5), the amplification amount calculation unit 27 is the 0-system variable amplification unit. The amount of amplification of 29a is calculated (step S6). The amplification amount calculation unit 27 obtains X [dB] (X [dB] = | A0−A1 |), and when X [dB] is larger than the set value P [dB], the interference amount is (X−P) [ dB], the control signal is output to the control unit 28 and the reception level reporting unit 22 by setting the amplification amount of the 0-system variable amplification unit 29a having a low signal level to (XP) [dB] (step S7). .
[0093]
In step S9, the amplification amount of the variable amplification unit 29a changes to (X−P) [dB]. In step S10, the reception level reporting unit 22 of the wireless unit 5a sets the amplification amount (X−P) [dB]. Considering this, the zero-system RF ′ signal level A0 ′ is calculated.
[0094]
In step S6, when X [dB] is equal to or smaller than P [dB], there is no interference, and therefore the amplification amount calculation unit 27 sets the amplification amount of the 0-system variable amplification unit 29a to 0 [dB] Is output to the control unit 28 and the reception level reporting unit 22 (step S8).
[0095]
In step S9, the amplification amount of the variable amplification unit 29a is changed to 0 [dB]. In step S10, the reception level reporting unit 22 considers the amplification amount 0 [dB], and the 0-system RF ′ signal level A0 ′. Is calculated.
[0096]
The same applies to the case where A1 <A1 'in step S2 and X [dB] is larger than P [dB] in step S6, and the description thereof will be omitted. However, the amplification amount of the one-system variable amplification unit 29b is (X−P) [dB].
[0097]
In step S6, the case where X [dB] is equal to or less than P [dB] is the same as described above, and the description thereof is omitted. However, the amplification amount of the 1-system variable amplification unit 29b is 0 [dB].
[0098]
Thus, it is apparent that the same effect as that of the embodiment of the present invention can be obtained by using another embodiment of the present invention using the variable amplifying sections 29a and 29b instead of the variable attenuation sections 8a and 8b.
[0099]
In another embodiment of the present invention, the amplification amount calculation unit 27 compares B0 and B0 ′ (compares B1 and B1 ′) and compares it with the set value P as X = | B0−B1 |. Even if it does, the effect similar to the Example of this invention is acquired.
[0100]
【The invention's effect】
The first effect of the present invention is that deterioration of reception sensitivity can be suppressed. The reason is that the amount of interference (attenuation) is calculated by monitoring the signals of both systems (the 0-system and 1-system high-frequency signals and the 0-system and 1-system intermediate frequency signals) at the front and rear stages of the radio unit. Depending on the amount of interference, the control means in the previous stage of the radio unit attenuates the signal of the system causing the interference, so that when a high-frequency signal with a high electric field is input to one system, the other This is because it is possible to suppress an increase in noise power due to interference with the reception band of the system.
[0101]
In addition, since the amount of interference can be calculated, the amount of attenuation of the signal of the system that causes interference can be minimized, so that the reception sensitivity of the system to which a high-field high-frequency signal is input is not deteriorated. .
[0102]
The second effect of the present invention is that the capacity of the system is not reduced. This is because, as described above, an increase in noise power due to interference can be suppressed, so that suppression of system capacity can be prevented.
[0103]
A third effect of the present invention is that a failure can be detected immediately. The reason is that by comparing the 0-system RF signal level with the 0-system RF ′ signal level, and by comparing the 1-system RF signal level with the 1-system RF ′ signal level, This is because the decline is monitored.
[Brief description of the drawings]
FIG. 1 is a diagram for explaining a diversity receiver 6 according to an embodiment of the present invention.
FIG. 2 is a diagram showing a configuration of diversity receiver 6 shown in FIG.
3 is a diagram showing a configuration of a radio unit 5a shown in FIG.
4 is a diagram showing a configuration of a detection unit 7 shown in FIG. 2. FIG.
FIG. 5 is a flowchart for explaining the operation of the diversity receiver 6 according to the embodiment of the present invention.
FIG. 6 is a diagram illustrating characteristics of the detectors 21a, 21b, 26a, and 26b.
FIG. 7 is a diagram illustrating characteristics of variable attenuation sections 8a and 8b.
FIG. 8 is a diagram illustrating a configuration of a diversity receiver according to another embodiment of the present invention.
FIG. 9 is a diagram for explaining a conventional diversity receiver.
10 is a diagram showing a configuration of diversity receiver 110 shown in FIG. 9. FIG.
11 is a diagram showing a configuration of a radio unit 120a shown in FIG.
[Explanation of symbols]
1 Radio base station equipment
2a, 2b Mobile terminal
3a-3f antenna
4a to 4f Low noise amplifier
5a Radio unit
6 Diversity receiver
7 detector
8a, 8b Variable attenuation part
9 Reception level calculator
10 Attenuation calculation unit
11, 28 Control unit
12a, 12b Amplifier
13a, 13b High frequency filter section
14, 18, 23a, 23b Synthesizer section
15, 19 Distribution section
16a, 16b, 20a, 20b, 24a, 24b Mixer section
17a, 17b, 25a, 25b Intermediate frequency filter section
21a, 21b, 26a, 26b detector
22 Reception level reporting section
27 Amplification amount calculation unit
29a, 29b Variable amplification section

Claims (12)

The 0-system and 1-system received radio frequency (RF) signals are amplified by a predetermined level and converted into the 0-system and 1-system intermediate frequency (IF) signals using the signals distributed from the common oscillation means, respectively. A diversity receiver including a radio unit for output,
First signal level calculating means for calculating the RF signal level of the 0 system and 1 system;
Second signal level calculation means for calculating the IF signal level of the 0 system and 1 system;
Based on the 0-system and 1-system RF signal levels and the 0-system and 1-system IF signal levels, the RF signal level that goes from the 0-system to the 1-system or from the 1-system to the 0-system is reduced. A diversity receiver including control means for controlling the RF signal levels of the 0-system and the 1-system. The control means is configured to circulate from the 0 system to the 1 system or from the 1 system to the 0 system based on the 0 system and 1 system RF signal levels and the 0 system and 1 system IF signal levels. a change amount calculating means calculates the respective change amounts of the RF signal level of the 0-system and 1-system so as to reduce,
2. A diversity receiver according to claim 1, further comprising level varying means for variably controlling the RF signal levels of the 0-system and 1-system corresponding to the amount of change. The 0-system and 1-system received radio frequency (RF) signals are amplified by a predetermined level and converted into the 0-system and 1-system intermediate frequency (IF) signals using the signals distributed from the common oscillation means, respectively. A diversity receiver including a radio unit for output,
First signal level calculating means for calculating the RF signal level of the 0 system and 1 system;
Second signal level calculation means for calculating the IF signal level of the 0 system and 1 system;
Control means for controlling the RF signal level of the 0 system and the 1 system based on the RF signal level of the 0 system and the 1 system and the IF signal level of the 0 system and the 1 system;
The control means calculates a change amount for calculating each change amount of the 0-system and 1-system RF signal levels based on the 0-system and 1-system RF signal levels and the 0-system and 1-system IF signal levels. Calculating means, and level variable means for variably controlling the RF signal levels of the 0-system and 1-system corresponding to the amount of change,
The change amount calculation means compares the 1-system RF ′ signal level, which is a value obtained by subtracting the gain in the radio unit from the 1-system IF signal level, and the 1-system RF signal level, and The absolute value of the difference between the 0-system RF signal level and the 1-system RF signal level is compared with a predetermined value, and the amount of attenuation, which is the amount of change in the 0-system RF signal level, according to these comparison results calculates the level varying means, features and to holder Iba City receiver that attenuates the RF signal of the 0 system in response to the attenuation.   When the RF signal level of the first system is smaller than the RF ′ signal level of the first system and the absolute value is larger than the predetermined value, the change amount calculating means calculates the absolute value and the predetermined value. The diversity receiver according to claim 3, wherein the difference is an attenuation amount of the RF signal level of the 0 system.   The change amount calculating means compares the 0-system RF ′ signal level, which is a value obtained by subtracting the gain in the radio unit from the 0-system IF signal level, and the 0-system RF signal level, The absolute value is compared with the predetermined value, and an attenuation amount that is a change amount of the RF signal level of the first system is calculated according to the comparison result, and the level variable means is configured to calculate the attenuation amount according to the attenuation amount. 5. The diversity receiver according to claim 3, wherein the RF signal of system 1 is attenuated.   The change amount calculating means, when the zero-system RF signal level is smaller than the zero-system RF ′ signal level and the absolute value is larger than the predetermined value, The diversity receiver according to claim 5, wherein the difference is an attenuation amount of the RF signal level of the first system.   The change amount calculating means corrects the attenuation amount of the 0-system RF signal level to obtain the 0-system RF ′ signal level, and corrects the attenuation amount of the RF signal level of the 1-system to correct the 1-system RF signal level. The diversity receiver according to claim 5, wherein the RF ′ signal level is obtained. The 0-system and 1-system received radio frequency (RF) signals are amplified by a predetermined level and converted into the 0-system and 1-system intermediate frequency (IF) signals using the signals distributed from the common oscillation means, respectively. A diversity receiver including a radio unit for output,
First signal level calculating means for calculating the RF signal level of the 0 system and 1 system;
Second signal level calculation means for calculating the IF signal level of the 0 system and 1 system;
Control means for controlling the RF signal level of the 0 system and the 1 system based on the RF signal level of the 0 system and the 1 system and the IF signal level of the 0 system and the 1 system;
The control means calculates a change amount for calculating each change amount of the 0-system and 1-system RF signal levels based on the 0-system and 1-system RF signal levels and the 0-system and 1-system IF signal levels. Calculating means, and level variable means for variably controlling the RF signal levels of the 0-system and 1-system corresponding to the amount of change,
The change amount calculating means compares the 0-system RF ′ signal level, which is a value obtained by subtracting the gain in the radio unit from the 0-system IF signal level, and the 0-system RF signal level, The absolute value of the difference between the 0-system RF signal level and the 1-system RF signal level is compared with a predetermined value, and the amount of amplification that is the amount of change in the 0-system RF signal level according to these comparison results calculates the level varying means, features and to holder Iba City receiver that amplifies the RF signal of the 0 system in response to the amount of amplification.   The change amount calculation means compares the 1-system RF ′ signal level, which is a value obtained by subtracting the gain in the radio unit from the 1-system IF signal level, and the 1-system RF signal level, and The absolute value is compared with the predetermined value, and an amplification amount that is a change amount of the RF signal level of the first system is calculated according to the comparison results, and the level variable means is configured to calculate the amplification amount according to the amplification amount. 9. The diversity receiver according to claim 8, wherein the first-system RF signal is amplified.   The change amount calculation means corrects the amplification amount of the 0-system RF signal level to obtain the 0-system RF ′ signal level, and corrects the amplification amount of the 1-system RF signal level to correct the 1-system RF signal level. The diversity receiver according to claim 9, wherein the RF ′ signal level is obtained.   The change amount calculation means outputs an alarm indicating that when the RF signal level of the first system is higher than the RF ′ signal level of the first system, The diversity receiver according to any one of 10.   12. The change amount calculating means outputs an alarm indicating this when the 0-system RF signal level is higher than the 0-system RF ′ signal level. Diversity receiver.

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