JP2010220053A - Base station device and radio communication method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a base station device and a radio communication method capable of preventing transmission function from markedly lowering under a high-temperature environment. <P>SOLUTION: When radio communication is performed with a mobile terminal device by using a diversity system, a carrier signal generated based on a baseband signal transmitted from the base station body device is generated by using plural transmission systems. The generated carrier signal is amplified by using a power amplifier, and radio waves are emitted separately by using the amplified carrier signal. Here, the temperature information representing the temperature of the power amplifier with respect to each of the plural transmission systems is acquired, and the output of the power amplifier is suppressed by making the power of the baseband signal lowered by a prescribed amount in response to the temperature information acquired. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a base station apparatus and a radio communication method for performing radio communication with a mobile terminal apparatus by a diversity method.

  Today, in wireless communication such as W-CDMA, for the purpose of lowering the installation cost of a base station and reducing the size of a base station installation location, an overhanging base station apparatus (RE: Remote Equipment) and a base station main body apparatus (REC) : Radio Equipment Control) is often used as a base station. The extended base station apparatus is provided apart from the base station main body apparatus that performs processing on the baseband signal of the mobile terminal apparatus, creates a carrier signal from the baseband signal, and performs orthogonal modulation, frequency conversion, and power amplification of the carrier signal. And transmit from the antenna to a mobile terminal device such as a mobile phone. A baseband signal is transmitted by optical communication between the base station body device and the extended base station device. Such an overhang base station device is smaller than the base station main unit, has a low installation cost, and can be installed in various environments, so the demand for a small overhang base station device is Big in recent years.

  By the way, the overhanging base station apparatus cools the power amplifier so as not to accumulate heat generated during power amplification. At this time, since the cooling fan generates noise and requires maintenance, it is not preferable to use the cooling fan. In the cooling by the air cooling method, the power amplifier is cooled by using the cooling fins. However, if the cooling fins are also reduced at the same time in order to reduce the size of the overhanging base station, the cooling effect may not be sufficiently obtained.

  For example, in an air-cooled system configuration provided with small cooling fins, in a high temperature environment, the internal temperature rises due to heat generated during power amplification, and the power amplifier is more likely to fail. For this reason, in order to avoid failure of the power amplifier, by providing a temperature monitoring function in the overhanging base station apparatus, the transmission output is stopped when the temperature reaches a high possibility of failure.

  FIG. 8 is a diagram showing a configuration of a conventional overhanging base station apparatus 100. As shown in FIG. The overhang base station apparatus 100 is a diversity system apparatus having two transmission systems. Each transmission system includes baseband processing units 102a and 102b, DA converters 104a and 104b, modulators 106a and 106b, power amplifiers 108a and 108b, failure detection units 110a and 110b, and an operation for controlling a transmission function. And a processing unit 112. The power amplifiers 108a and 108b are connected to the antennas 114a and 114b.

  The baseband processing units 102a and 102b are parts that perform filtering processing, distortion compensation processing, interpolation processing, and the like on the I signal and Q signal transmitted from the base station main unit, and the processed signal is the DA converter 104a. , 104b are converted into analog signals. Modulators 106a and 106b perform frequency conversion on the analog signal by quadrature modulation and up-conversion to generate a carrier wave signal. The power amplifiers 108a and 108b amplify the carrier signal and generate an output carrier signal. This output carrier signal is fed to the antennas 114a and 114b.

  Failure detection units 110a and 110b detect the temperature of power amplifiers 108a and 108b. The arithmetic processing unit 112 uses the detected temperature to compare whether the power amplifiers 108a and 108b are in a high temperature state or a set temperature threshold value. If it is determined that the processing unit 112 is in a high temperature state, the arithmetic processing unit 112 controls the power amplifiers 108a and 108b so as to amplify the power amplifiers 108a and 108b and stop the transmission output that radiates radio waves from the antennas 114a and 114b.

Further, Patent Document 1 below describes a wireless transmission device that has a temperature monitoring function in a power amplifier and stops transmission output when reaching a dangerous temperature at which the possibility of occurrence of failure increases.
In the wireless transmission device described in the document, transmission signals such as voice and data are encoded by the encoding unit, and in the signal processing system for antenna A, predetermined signal processing is performed by the signal processing unit for antenna A and spread. In the modulation unit, spreading and modulation are performed. In the transmission power amplification unit, after power amplification is performed, transmission is performed via the antenna A. In the antenna B signal processing system, a transmission signal is similarly formed. When a failure occurred in a part related to the transmission diversity function of the base station device, the failure detection unit detected the failure, and the processing switching setting unit stopped the function of the signal processing system that detected the failure, and no failure was detected. Switch to the setting for normal transmission from the signal processing system. Further, when detecting a failure related to the transmission diversity function, the process switching setting unit increases the transmission power of the transmission signal formed by the signal forming system in which the failure is not detected as compared to when transmission diversity is applied.

JP 2003-169006 A

  However, in the wireless transmission device described in the above document, since one transmission function is completely stopped in a high temperature environment, there arises a problem that the transmission function is remarkably deteriorated. In addition, since a failure is detected, there is a problem that transmission stop is unavoidable.

  Accordingly, an object of the present invention is to provide a base station apparatus and a wireless communication method capable of preventing a transmission function from being significantly lowered even in a high temperature environment in order to solve the problems of the prior art.

The above purpose is
(A) an adjustment unit for adjusting the output of the transmission signal;
(B) an amplification unit that amplifies the transmission signal whose output is adjusted by the output adjustment unit;
(C) a detection unit for detecting temperature information of the amplification unit;
(D) based on a comparison between the temperature information detected by the detection unit and a predetermined threshold, a control unit for controlling the output adjustment amount of the adjustment unit;
Can be reached by a base station apparatus equipped with
This base station apparatus performs radio communication with a mobile terminal apparatus by a diversity method, for example.

The above object can also be achieved by a wireless communication method described below that performs wireless communication with a mobile terminal apparatus using a diversity method. That is, the wireless communication method is
(E) generating a carrier wave signal from a baseband signal transmitted from the base station main unit using a plurality of transmission systems;
(F) amplifying the generated carrier wave signal using a power amplifier and radiating radio waves using the amplified carrier wave signal;
(G) acquiring temperature information representing the temperature of the power amplifier for each of the plurality of transmission systems, and adjusting the power of the baseband signal for each of the plurality of transmission systems according to the acquired temperature information Steps.

  The above-described overhanging base station apparatus and wireless communication method can prevent the transmission function from being significantly lowered even in a high temperature environment.

It is a figure which shows the structure of the protrusion base station apparatus of one Embodiment in the protrusion base station apparatus of this invention. (A), (b) is a figure explaining the temperature control performed with the overhang | projection base station apparatus shown in FIG. It is a flowchart which shows an example of the temperature control process performed with the overhang | projection base station apparatus shown in FIG. It is a flowchart which shows the other example of the temperature control process performed with the overhang | projection base station apparatus shown in FIG. (A), (b) is a figure which shows the structure of the extension base station apparatus of other embodiment in the extension base station apparatus of this invention. (A), (b) is a figure which shows the example of the address signal and gain table which the extended base station apparatus shown to Fig.5 (a) uses. It is a figure which shows the structure of the overhang | projection base station apparatus which deform | transformed the overhang | projection base station apparatus shown to Fig.5 (a). It is a figure which shows the structure of the conventional overhang | projection base station apparatus.

  Hereinafter, the base station apparatus and the wireless communication method of the present invention will be described in detail.

[First embodiment]
FIG. 1A is a diagram illustrating a configuration of a base station apparatus (hereinafter referred to as an apparatus) 10 according to an embodiment of the base station apparatus of the present invention.
The device 10 is a device that performs wireless communication with a mobile terminal device located in a service area by a diversity method, and can be used for wireless communication such as W-CDMA, for example. The apparatus 10 includes a normal transmission mode in which radio waves are emitted with a predetermined transmission output, and a transmission power suppression mode in which the transmission power is reduced by 6 dB with respect to the transmission power in the normal transmission mode in order to suppress an increase in temperature of the power amplifier. And a stop mode for temporarily stopping transmission.
As will be described later, the device 10 includes two transmission systems having the same device configuration, but can also include a plurality of transmission systems such as three systems and four systems.

(Configuration of device 10)
The apparatus 10 includes a bit shift processing unit 12a, 12b, a baseband processing unit 14a, 14b, a DA converter 16a, 16b, a modulator 18a, 18b, a power amplifier 20a, 20b, an antenna 22a, 22b, a temperature It has detection units 24 a and 24 b and a processing unit (CPU) 26. That is, the bit shift processing unit 12a, the baseband processing unit 14a, the DA converter 16a, the modulator 18a, the power amplifier 20a, and the antenna 22a form a transmission system A, the bit shift processing unit 12b, The band processing unit 14b, the DA converter 16b, the modulator 18b, the power amplifier 20b, and the antenna 22b constitute the other transmission system B. The apparatus 10 generates a signal for controlling transmission power by activating and operating software in the processing unit 26.

The baseband processing units 12a and 12b receive digital signal I and Q signals transmitted from the base station main unit, and perform filtering processing, distortion compensation processing, interpolation processing, and the like on the I and Q signals. The baseband processing is performed by, for example, a DSP (Digital Signal Processor).
The DA converters 14a and 14b convert the baseband processed signals into analog signals.
The modulators 16a and 16b perform frequency conversion by orthogonal modulation and up-conversion on the analog signal to generate a carrier wave signal.
The power amplifiers 18a and 18b are amplified to a carrier signal having a transmission power of 20 to 40 W using an amplifier such as a Doherty amplifier, and the antennas 22a and 22b radiate radio waves using the amplified carrier signals.
The temperature detectors 24a and 24b are portions that measure temperature of the power amplifiers 20a and 20b and acquire temperature data, and sensors such as a temperature sensor IC are used. Sensors are provided on the substrates of the power amplifiers 20a and 20b.

  The processing unit 26 determines whether or not the temperature of the power amplifiers 20a and 20b is in a high temperature state using the temperature data acquired by the temperature detection units 24a and 24b, and determines the power of the input signal according to the determination result. When the temperature of the power amplifiers 20a and 20b is suddenly increased, the amplification of the power amplifiers 20a and 20b is stopped and the transmission function is stopped.

The bit shift processing units 12a and 12b are provided in front of the baseband processing units 14a and 14b, and adjust the output of the transmission signal according to the control of the processing unit 26. The bit shift processing units 12a and 12b perform adjustment to reduce the signal level (power) of the input I signal and Q signal. For example, the temperature detected by the temperature detection unit 24a in the transmission system A is kept substantially constant as shown in FIG. 2A, and the temperature detected by the temperature detection unit 24b in the transmission system B is shown in FIG. when exceeding the temperature threshold value T _th as shown, from the time t _a at which exceeds at time t _b, which has passed a predetermined time in a state exceeding the temperature threshold value T _th, a reduction in the bit shift with respect to the input signal Start. That is, the transmission system B shifts from the normal transmission mode to the transmission power suppression mode. Thereby, as shown in FIG. 2B, the transmission power in the power amplifier 20b is reduced by 6 dB with respect to the transmission power W in the normal transmission mode set in advance. The transmission system A maintains the normal transmission mode.

Furthermore, the bit shift processing unit 12a, 12b is due to a decrease in transmission power, when the temperature of the power amplifier 20b in the transmission system B falls below the temperature threshold value T _th, from the time t _c when below the temperature threshold value T _th At a time t _d when a certain time has elapsed in the lower state, the reduction of the bit shift with respect to the input signal is finished, the output power is increased by 6 dB as shown in FIG. 2B, and the original state is restored. That is, the transmission system B returns from the transmission power suppression mode to the normal transmission mode. FIG. 2A also shows the alarm temperature T _max of the power amplifiers 20a and 20b. The alarm temperature _Tmax is a value determined for the power amplifiers 20a and 20b. The alarm temperature _Tmax is a temperature at which an alarm is to be issued, which is very likely to cause a failure. In FIG. 2A, as an example, the alarm temperature T _max = 90 ° C. and the temperature threshold T _th = 85 ° C. are used, but the present invention is not limited to these temperatures. Of course, it is not limited that the temperature threshold T _th is set to a temperature 5 ° C. lower than the alarm temperature T _max =.
Thus, since the transmission power suppression mode is provided, the number of times that one transmission function is completely stopped can be extremely reduced.

  In such a device 10, first, a carrier wave signal is generated from the baseband signal transmitted from the base station main body device through the baseband processing units 14 a and 14 b, the DA converters 16 a and 16 b, and the modulators 18 a and 18 b. The generated carrier wave signals are amplified using power amplifiers 20a and 20b, and radio waves are radiated from antennas 22a and 22b using the amplified carrier wave signals, respectively. At that time, the temperature data of the power amplifiers 20a and 20b is acquired for each of the transmission systems A and B, and the output of the power amplifiers 20a and 20b is reduced by reducing the power of the baseband signal by 6 dB according to the acquired temperature data. Suppress. Hereinafter, suppression of the outputs of the power amplifiers 20a and 20b will be described in detail.

(Transition from normal transmission mode to transmission power suppression mode or transmission stop mode)
FIG. 3 is a flowchart showing a flow of transition from the normal transmission mode to the transmission power suppression mode or the transmission stop mode when the temperature of the power amplifiers 20a and 20b becomes high.
First, in the temperature detectors 24a and 24b, the temperature data T of the power amplifiers 20a and 20b are sampled and acquired at a constant time interval, for example, every 2 seconds (step S10). The acquired temperature data T is sent to the processing unit 26.

In the processing unit 26, it is determined whether or not each of the transmitted temperature data T of the transmission systems A and B has exceeded a predetermined temperature threshold T _th (step S12). Here, the temperature threshold T _th is a temperature set lower than the alarm temperature T _max .
When there is a transmission system in which the determination result is negative (No), the process returns to step S10, and acquisition of the temperature data T is continued at regular time intervals. On the other hand, if the determination result is affirmative (Yes), the processing unit 26, the count value N is set to 0 (step S14), and further, whether the count value N is the number of times the threshold value N _th than the predetermined Is determined (step S16). At this time, if the determination result is negative (No), the count value N is increased by 1, and the temperature data T is acquired again (step S18). The acquisition of the temperature data T at this time is performed at the predetermined time intervals described above. Next, it is determined whether or not the acquired temperature data T still exceeds the temperature threshold T _th (step S20). If this determination result is negative (No), the process returns to step S10, and the acquisition of the temperature data T and the determination of the temperature in step S12 are continued again. On the other hand, when the judgment result is affirmative (Yes) at step S20, the count value N is the determination of whether or not the number of times the threshold value N _th or more is performed in step S16. Thus, the temperature data T exceeds the temperature threshold value T _th, and until the count value N is equal to the count threshold N _th, step S16, S18, S20 are repeated. Since the temperature data is acquired at regular time intervals, the time obtained by multiplying the predetermined time interval the number of times the threshold N _th corresponds to (t b _{-t a)} time in FIG. 2 (b).

In step S16, when the count value N is determined to be the threshold value of the number N _th or more, then, the temperature gradient (temperature change) [Delta] T is calculated (step S22). The temperature gradient ΔT is the previous temperature data T ₍ acquired before m (m is an integer from 1 to N _th ) times) set in advance from this temperature data T _N , where T _N is the latest acquired temperature data. _Nm) is the difference. The reason for calculating such a temperature gradient ΔT is to control the transmission power in response to a rapid temperature increase.

Next, it is determined whether or not the calculated temperature gradient ΔT exceeds a preset temperature gradient threshold value ΔT _th (step S24). If the determination result is negative (No), the process proceeds to a transmission power suppression mode in which the transmission power is reduced by 6 dB (step S26). In the transmission output suppression mode, the bit shift processing unit 12a or the bit shift processing unit 12b reduces the signal value of the input signal, which is a digital signal, by bit shifting.
On the other hand, when the determination result is affirmative (Yes), there is a high risk that the temperature of the power amplifier 24a or the power amplifier 24b will reach the alarm temperature T _max , so the mode is shifted to the transmission stop mode (step S28). That is, the output of the power amplifier 24a or the power amplifier 24b is stopped, and transmission is stopped. Such processing is performed for each of the transmission systems A and B.

As described above, the apparatus 10 includes the transmission power suppression mode in which the transmission power of the transmission system A or the transmission system B is temporarily reduced before reaching the alarm temperature _Tmax. The temperature rise can be suppressed so that the temperature of the amplifiers 20a and 20b does not reach the alarm temperature _Tmax . That is, instead of detecting a failure as in the conventional case, the transmission power is controlled so as not to reach a temperature at which the power amplifier fails. Therefore, the number of times transmission output is stopped is extremely small compared to the conventional case. Also, in the diversity transmission power suppression mode, the transmission function of one transmission system is not completely stopped as in the prior art, so that the transmission function is not significantly reduced.

(Transition from transmission power suppression mode or transmission stop mode to normal transmission mode)
FIG. 4 is a flowchart showing a flow of transition from the transmission power suppression mode and the transmission stop mode to the normal transmission mode.

In the transmission power suppression mode or the transmission stop mode, the temperature detection units 24a and 24b sample and acquire the temperature data T of the power amplifiers 20a and 20b at a constant time interval, for example, every 2 seconds (step S40). . The acquired temperature data T is sent to the processing unit 26.
In the processing unit 26, it is determined whether or not each of the transmitted temperature data T of the transmission systems A and B is lower than a predetermined temperature threshold value _Tth (step S42).
If the determination result is negative (No), the process returns to step S40, and acquisition of the temperature data T is continued at regular time intervals. On the other hand, if the determination result is affirmative (Yes), the processing unit 26, the count value N is set to 0 (step S44), further, whether the count value N is the number of times the threshold value N _th than the predetermined Is determined (step S46). If the determination result is negative (No), the count value N is increased by 1, and the temperature data T is acquired again (step S48). Acquisition of the temperature data T at this time is performed at the above-mentioned fixed time intervals. Therefore, the time obtained by multiplying the number threshold N _th by a certain time interval corresponds to the time of (t _d −t _c ) in FIG. Note that the number threshold N _th used in step S46 may be the same value as the number threshold N _th used in step S16 shown in FIG. 3 or may be a different value.

Next, it is determined whether or not the acquired temperature data T is still below the temperature threshold T _th (step S50). If this determination result is negative (No), the process returns to step S40, and the acquisition of the temperature data T and the determination in step S42 are continued again. On the other hand, if the determination result in step S50 is affirmative (Yes), the count value N is determined in step S46. Thus, the temperature data T is below the temperature threshold value T _th, and until the count value N is equal to the count threshold N _th, step S46, S48, S50 are repeated. If the determination result is affirmative (Yes) in step S46, it is determined that the temperature T has sufficiently decreased with respect to the temperature threshold value _Tth , and the normal transmission mode is entered (step S52). Such processing is performed for the transmission system in the transmission power suppression mode or the transmission stop mode.

As described above, when the temperature data of the power amplifiers 20a and 20b surely decreases with respect to the temperature threshold value _Tth , the normal transmission mode is promptly shifted, so that the period during which the transmission power is reduced or the transmission function is reduced is minimized. To the limit.

[Second Embodiment]
FIG. 5A is a diagram illustrating a configuration of an overhanging base station device (hereinafter, referred to as a device) 30 according to another embodiment different from the configuration of the device 10 illustrated in FIG.
The apparatus 10 shown in FIG. 1 controls transmission power by executing software using the arithmetic processing unit 26, but the apparatus 30 is configured to control transmission power using a dedicated circuit.

  The device 30 includes two transmission systems having the same device configuration, and includes gain adjustment units 42a and 42b, baseband processing units 44a and 44b, DA converters 46a and 46b, modulators 48a and 48b, and a power amplifier 50a, 50b, antennas 52a and 52b, temperature detectors 54a and 54b, and an output data generation circuit 56. That is, the baseband processing units 44a and 44b, the DA converters 46a and 46b, the modulators 48a and 48b, the power amplifiers 50a and 50b, the antennas 52a and 52b, and the temperature detection units 54a and 54b are shown in FIG. Since the same parts as the corresponding parts shown are used, description of these parts is omitted.

The gain adjustment units 42 a and 42 b are portions that adjust the gain of the input signal according to the set value sent from the output data generation circuit 56.
As shown in FIG. 5B, the output data generation circuit 56 uses the temperature data # 0 and temperature data # 1 sent from the temperature detectors 54a and 54b to set values for adjusting the gain of the input signal. Is generated. The temperature data # 0 is temperature data T sent from the temperature detection unit 54a of the transmission system A, and the temperature data # 1 is temperature data T sent from the temperature detection unit 54b of the transmission system B. The output data generation circuit 56 includes a threshold comparator 58 including a comparator, an N counter 60, a gain table 62, a temperature history buffer 64, and an address generation circuit 66.

The temperature detectors 54a and 54b detect temperature in the power amplifiers 50a and 50b at regular time intervals to acquire temperature data, and sequentially send the temperature data # 0 and # 1 to the output data generation circuit 56 at regular time intervals.
The threshold value comparison circuit 58 compares the temperature data # 0 and the temperature data # 1 sent sequentially with a preset temperature threshold value T _th, and when the temperature data T crosses the temperature threshold value T _th , A count start signal for starting counting is generated. Furthermore, the threshold comparator circuit 58, when obtaining the temperature data exceeding a temperature threshold value T _th, obtains the threshold value over a signal indicating that it has acquired temperature data exceeding a temperature threshold value T _th, the temperature data below the temperature threshold value T _th Then, a threshold under signal indicating that temperature data lower than the temperature threshold T _th has been acquired is generated and output to the N counter 60.

When the count start signal is sent from the threshold comparison circuit 58, the N counter 60 starts counting the number of times of the threshold over signal or the threshold under signal (count value N) and continuously sends it at a constant time interval. Incoming threshold over or under threshold signals are counted. In this way, the count value N when the temperature data continuously sent at a constant time interval is continuously higher or lower than the temperature threshold value _{Tth is} obtained. When the count N becomes equal to the count threshold N _th, N counter 60 sends a gain control signal to the gain table 62.

On the other hand, the temperature history buffer 64 records a predetermined number of data (m) of temperature data # 0 and # 1 that are sequentially sent at regular time intervals. The temperature history buffer 64 sends the latest temperature data and the m-th previous temperature data to the address generation circuit 66.
The address generation circuit 66 obtains a difference between the latest temperature data sent and the m-th previous temperature data as a temperature gradient ΔT. The address generation circuit 66 generates an address including information on the temperature gradient ΔT and information for specifying a transmission system (system A or system B) to be gain-adjusted, and sends the address to the gain table 62. As for the transmission system to be gain-adjusted, the transmission system having the higher temperature data among the temperature data # 0 and # 1 is determined.

  FIG. 6A is a diagram for explaining an example of an address generated by the address generation circuit 66. The address shown in FIG. 6 (a) is a 4-bit address, the upper 1 bit indicates information specifying the transmission system (A or B) to be gain-adjusted, and the lower 3 bits indicate the temperature gradient ΔT as 3 bits. Data information.

The gain table 62 uses the address sent from the address generation circuit 66 to generate a setting value for gain adjustment in the gain adjustment units 42a and 42b, and sends the setting value to the gain adjustment units 42a and 42b.
FIG. 6B is a diagram illustrating an example of a reference table recorded in the gain table 62. In the reference table shown in FIG. 6B, set values for controlling the transmission power of the system A are set in the addresses “0h” to “7h”, and the transmission of the transmission system B is set in the addresses “8h” to “Fh”. A set value for controlling power is set. For example, at addresses “1h” to “3h” indicating that the temperature gradient ΔT is smaller than the temperature gradient threshold value ΔT _th , the setting value for adjusting the gain of the input signal of the transmission system A so as to execute the transmission power suppression mode Y is determined. At addresses “4h” to “7h” indicating that the temperature gradient ΔT is larger than the temperature gradient threshold ΔT _th , a set value 0 for adjusting the gain of the input signal of the transmission system A is determined so as to execute the transmission stop mode. It is done. When the temperature gradient ΔT is substantially 0, a set value X for adjusting the gain of the input signal of the transmission system A is determined so as to execute the normal transmission mode.
As described above, the set values corresponding to the normal transmission mode, the transmission power suppression mode, or the transmission stop mode are sent to the gain adjustment units 42a and 42b according to the address.

As with the device 10, the device 30 includes a transmission power suppression mode in which the transmission power of the transmission system A or the transmission system B is temporarily reduced before reaching the alarm temperature _Tmax , so that the transmission function is maintained. The temperature rise can be suppressed so that the temperature of the power amplifiers 50a and 50b does not reach the alarm temperature _Tmax . That is, instead of detecting a failure as in the conventional case, the transmission power is controlled so as not to reach a temperature at which the power amplifier fails. Therefore, the number of times transmission output is stopped is extremely small compared to the conventional case. Also, in the diversity transmission power suppression mode, the transmission function of one transmission system is not completely stopped as in the prior art, so that the transmission function is not significantly reduced.

[Modification of Second Embodiment]
FIG. 7 shows a device 60 obtained by modifying the device 30 shown in FIG.
The device 60 estimates the temperature data of the power amplifiers 50a and 50b by using the temperature data of the external environment temperature and the transmission power of the power amplifiers 50a and 50b to estimate the temperature data of the power amplifiers 50a and 50b. And different.

Device 60. Similar to the apparatus 30 shown in FIG. 5 (a), gain adjusting units 42a and 42b, baseband processing units 44a and 44b, DA converters 46a and 46b, modulators 48a and 48b, and power amplifiers 50a and 50b. The antennas 52a and 52b and the output data generation circuit 56 are included, and the temperature detectors 54a and 54b are not included. Device 60. Instead of having the temperature detectors 54a and 54b, transmission output detectors 68a and 68b and an external temperature information acquisition unit 70 are provided.
The transmission output detectors 68 a and 68 b are configured by a circuit that detects transmission power that is actually amplified and output by the power amplifiers 50 a and 50 b, and supplies the detected transmission output to the output data generation circuit 56.
On the other hand, the external temperature information acquisition unit 70 includes a temperature sensor that measures the external environment temperature, and supplies information about the current external environment temperature detected by the temperature sensor to the output data generation circuit 56.

Based on the transmission output sent from the transmission output detectors 68a and 68b, the output data generation circuit 56 calculates the temperature rise of the power amplifiers 50a and 50b from the external environment temperature based on the transmission output. Specifically, since the temperature rise is obtained by multiplying the detected transmission output by the thermal resistance value, it can be defined by a function using the transmission output as a parameter. Therefore, the output data generation circuit 56 creates and stores this function in advance, and obtains the temperature rise from the transmitted output.
Furthermore, the output data generation circuit 56 estimates and acquires the temperature data # 0 and # 1 of the power amplifiers 50a and 50b by adding the above-mentioned temperature rise to the transmitted external environment temperature information. Using the temperature data # 0 and # 1, processing similar to that of the device 30 is performed. That is, the external temperature information acquisition unit 70, the transmission output detection units 68a and 68b, and the output data generation circuit 56 function as a temperature information acquisition unit, and the temperature data # 0 and # 1 are acquired.
The device 60 uses a temperature sensor as the external temperature information acquisition unit 70. However, any method may be used as long as the external environment temperature can be acquired. For example, an external environment from a host device such as a base station body device can be used. You may comprise so that the information of temperature may be acquired.

Similarly to the apparatus 30, the apparatus 60 includes a transmission power suppression mode in which the transmission power of the transmission system A or the transmission system B is temporarily reduced before reaching the alarm temperature _Tmax , so that the transmission function is maintained. However, the temperature rise can be suppressed so that the temperature of the power amplifiers 50a and 50b does not reach the alarm temperature _Tmax . That is, instead of detecting a failure as in the conventional case, the transmission power is controlled so as not to reach a temperature at which the power amplifier fails. Therefore, the number of times transmission output is stopped is extremely small compared to the conventional case. Further, in the transmission power suppression mode in diversity transmission, the transmission function of one transmission system is not completely stopped as in the prior art, and therefore the transmission function is not significantly reduced.

Regarding the above embodiment, the following supplementary notes are disclosed.

(Appendix 1)
A base station apparatus that performs radio communication with a mobile terminal apparatus using a diversity method,
An adjustment unit that adjusts the power of the baseband signal, a signal processing unit that generates a carrier signal based on the baseband signal whose power is adjusted, a power amplifier that amplifies the generated carrier signal, and an amplified signal A transmission unit including a plurality of transmission systems including an antenna that radiates radio waves using the carrier wave signal;
A temperature information acquisition unit for acquiring temperature information of each of the power amplifiers of a plurality of transmission systems;
A control unit that controls a power adjustment amount of the adjustment unit according to the temperature information acquired by the temperature information acquisition unit for each of the plurality of transmission systems;
A base station apparatus comprising:

(Appendix 2)
The temperature information acquisition unit acquires the temperature information at regular time intervals,
When there is a transmission system in which the temperature information exceeds a preset first temperature threshold value for a predetermined number of times, the control unit continues the temperature information for a predetermined number of times. The base station apparatus according to supplementary note 1, wherein the power adjustment amount is controlled so as to reduce a power of a baseband signal used by a transmission system exceeding the predetermined amount.

(Appendix 3)
In the transmission system in which the power of the baseband signal is reduced to suppress the output of the power amplifier, when the temperature information is continuously below the first temperature threshold for a predetermined number of times, the control unit The base station apparatus according to appendix 2, wherein the power adjustment amount is controlled so as to end the power reduction of the band signal.

(Appendix 4)
When the temperature change obtained from the temperature information exceeds a predetermined value, the control unit
The base station apparatus according to any one of appendices 1 to 3, wherein the power adjustment amount is controlled so as to stop the output of a transmission-system power amplifier in which the temperature change exceeds a predetermined value.

(Appendix 5)
The temperature information acquisition unit includes an environmental temperature information acquisition unit that acquires an environmental temperature around the overhanging base station device, a transmission power detection unit that detects transmission power of the power amplifier, and the environmental temperature and the transmission power. The base station apparatus according to any one of appendices 1 to 4, further comprising: a processing unit that acquires a result of addition with the calculated internal temperature rise amount of the power amplifier as the temperature information.

(Appendix 6)
A wireless communication method for performing wireless communication with a mobile terminal device using a diversity method,
Generating a carrier signal from a baseband signal transmitted from the base station main unit using a plurality of transmission systems;
Amplifying the generated carrier signal using a power amplifier and radiating radio waves using the amplified carrier signal;
Acquiring temperature information representing the temperature of the power amplifier for each of the plurality of transmission systems, and adjusting the power of the baseband signal according to the acquired temperature information for each of the plurality of transmission systems; A wireless communication method comprising:

(Appendix 7)
The temperature information is acquired at regular time intervals,
When there is a transmission system in which the temperature information exceeds a preset first temperature threshold value for a predetermined number of times, the adjustment unit is configured so that the temperature information continues the first temperature threshold value for a predetermined number of times. The wireless communication method according to appendix 6, wherein the power of a baseband signal used by a transmission system exceeding the specified value is reduced by a predetermined amount.

(Appendix 8)
In the transmission system in which the power of the baseband signal is reduced to suppress the output of the power amplifier, when the temperature information is continuously lower than the first temperature threshold for a predetermined number of times, the adjustment unit The wireless communication method according to appendix 7, wherein the power reduction of the band signal is terminated.

(Appendix 9)
Furthermore, when the temperature change calculated | required from the said temperature information exceeds a predetermined value, the step which stops the output of the power amplifier of the transmission system in which the said temperature change exceeds a predetermined value has the step of appendix 6 which has Wireless communication method.

(Appendix 10)
An output adjustment unit for adjusting the output of the transmission signal;
An amplifying unit for amplifying the transmission signal whose output is adjusted by the output adjusting unit;
A detection unit for detecting temperature information of the amplification unit;
A control unit that controls an output adjustment amount of the output adjustment unit based on a comparison between temperature information detected by the detection unit and a predetermined threshold;
A base station apparatus comprising:

In a base station apparatus that performs diversity transmission using a plurality of antennas,
For each of the plurality of antennas, an output adjustment unit that adjusts the output of the transmission signal, an amplification unit that amplifies the transmission signal whose output is adjusted by the output adjustment unit,
In addition,
A detection unit for detecting temperature information of the amplification unit;
A control unit that controls an output adjustment amount of the output adjustment unit based on a comparison between temperature information detected by the detection unit and a predetermined threshold;
A base station apparatus comprising:

  The base station apparatus and the wireless communication method of the present invention have been described in detail above. However, the present invention is not limited to the above-described embodiment, and various improvements and modifications may be made without departing from the gist of the present invention. Of course.

10, 30 Overhang base station apparatus 12a, 12b Bit shift processing units 14a, 14b, 44a, 44b Baseband processing units 16a, 16b, 46a, 46b DA converters 18a, 18b, 48a, 48b Modulators 20a, 20b, 50a, 50b Power amplifiers 22a, 22b, 52a, 52b Antennas 24a, 24b, 54a, 54b Temperature detector 26 Processing unit (CPU)
42a, 42b Gain adjustment unit 56 Output data generation circuit 58 Threshold comparison circuit 60 N counter 62 Gain table 64 Temperature history buffer 66 Address generation unit 68a, 68b Transmission power detection unit 70 External temperature information acquisition unit

Claims (8)

A base station apparatus that performs radio communication with a mobile terminal apparatus using a diversity method,
An adjustment unit that adjusts the power of the baseband signal, a signal processing unit that generates a carrier signal based on the baseband signal whose power is adjusted, a power amplifier that amplifies the generated carrier signal, and an amplified signal A transmission unit including a plurality of transmission systems including an antenna that radiates radio waves using the carrier wave signal;
A temperature information acquisition unit for acquiring temperature information of each of the power amplifiers of a plurality of transmission systems;
A control unit that controls a power adjustment amount of the adjustment unit according to the temperature information acquired by the temperature information acquisition unit for each of the plurality of transmission systems;
A base station apparatus comprising: The temperature information acquisition unit acquires the temperature information at regular time intervals,
When there is a transmission system in which the temperature information exceeds a preset first temperature threshold value for a predetermined number of times, the control unit continues the temperature information for a predetermined number of times. The base station apparatus according to claim 1, wherein the power adjustment amount is controlled so as to reduce a power of a baseband signal used by a transmission system exceeding a predetermined amount.   In the transmission system in which the power of the baseband signal is reduced to suppress the output of the power amplifier, when the temperature information is continuously below the first temperature threshold for a predetermined number of times, the control unit The base station apparatus according to claim 1, wherein the power adjustment amount is controlled so as to end the power reduction of the band signal. When the temperature change obtained from the temperature information exceeds a predetermined value, the control unit
The base station apparatus according to any one of claims 1 to 3, wherein the power adjustment amount is controlled so that an output of a power amplifier of a transmission system in which the temperature change exceeds a predetermined value is stopped.   The temperature information acquisition unit is calculated from an environmental temperature information acquisition unit that acquires an environmental temperature around the base station device, a transmission power detection unit that detects transmission power of the power amplifier, and the environmental temperature and the transmission power 5. The base station apparatus according to claim 1, further comprising: a processing unit that acquires a result of addition with the amount of increase in the internal temperature of the power amplifier as the temperature information. A wireless communication method for performing wireless communication with a mobile terminal device using a diversity method,
Generating a carrier signal from a baseband signal transmitted from the base station main unit using a plurality of transmission systems;
Amplifying the generated carrier signal using a power amplifier and radiating radio waves using the amplified carrier signal;
Acquiring temperature information representing the temperature of the power amplifier for each of the plurality of transmission systems, and adjusting the power of the baseband signal according to the acquired temperature information for each of the plurality of transmission systems; A wireless communication method comprising: An output adjustment unit for adjusting the output of the transmission signal;
An amplifying unit for amplifying the transmission signal whose output is adjusted by the output adjusting unit;
A detection unit for detecting temperature information of the amplification unit;
A control unit for controlling an output adjustment amount of the adjustment unit based on a comparison between the temperature information detected by the detection unit and a predetermined threshold;
A base station apparatus comprising: In a base station apparatus that performs diversity transmission using a plurality of antennas,
For each of the plurality of antennas, an output adjustment unit that adjusts the output of the transmission signal, an amplification unit that amplifies the transmission signal whose output is adjusted by the output adjustment unit,
In addition,
A detection unit for detecting temperature information of the amplification unit;
A control unit for controlling an output adjustment amount of the adjustment unit based on a comparison between the temperature information detected by the detection unit and a predetermined threshold;
A base station apparatus comprising: