JP2005027173A - Transmitting part control method of radio communication equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a transmitting part control method for reducing power consumption and achieving the miniaturization and weight reduction of radio communication equipment with an active system transmitting part which is in a communication state and a reserve system transmitting part which does not perform communication. <P>SOLUTION: The method has a means for turning off a power source of a power amplifier of a transmitting part and sets a power source of a power amplifier of the reserve system transmitting part which is not usually used in an off-state by a power-off means. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for controlling a transmission unit of a wireless communication device, and more particularly to a method for controlling the transmission unit in a duplexed wireless communication device including an active transmission unit and a standby transmission unit.
[0002]
[Prior art]
[Patent Document 1]
JP 2003-115805 A
Conventionally, as disclosed in Patent Document 1, a wireless communication device in a microwave band provided with an active transmission unit and a standby transmission unit can always communicate not only with an active transmission unit but also with a standby transmission unit. State.
[0004]
[Problems to be solved by the invention]
However, if not only the active transmission unit but also the standby transmission unit is set in a state where communication is always possible, there is a problem that power consumption during normal operation becomes large. Moreover, since the calorific value is large, a large radiator is required, and there is a problem that the size and weight are increased.
[0005]
The present invention has been made in view of the above points, and an object of the present invention is to provide a method for controlling a transmission unit of a wireless communication device that can reduce power consumption of the wireless communication device and can be reduced in size and weight. .
[0006]
[Means for Solving the Problems]
According to another aspect of the present invention, there is provided a method for controlling a transmission unit of a wireless communication apparatus, including: a wireless communication apparatus including an active transmission unit that is in a communication state and a standby transmission unit that is not performing communication; The power amplifier of the standby transmission unit is set to an off state by the power-off means.
[0007]
Such a transmission unit control method of the present invention includes means for detecting when a failure occurs in the active transmission unit and generating a switching signal, and when the switching signal is generated by this unit, the standby transmission unit Means for turning on the power of the power amplifier, means for switching the high-frequency output to the standby transmission unit side which is in an operating state by turning on the power of the power amplifier by the power-on means, and the high-frequency output by the switching means It is preferable to further comprise means for turning off the power of the power amplifier of the active transmission unit by the power off unit when switched to the standby transmission unit side. Further, the switching means monitors the high-frequency output level of the standby transmission unit that is in an operating state, and switches the high-frequency output to the standby transmission unit side when the high-frequency output level falls within a predetermined range. Is preferred. Furthermore, it is preferable that detection of a failure occurring in the active transmission unit and generation of a switching signal are performed in the wireless communication device using a signal from a circuit in the active transmission unit.
[0008]
Further, the transmission unit control method of the present invention includes a health check unit that turns on the power of the power amplifier of the standby transmission unit to check the operation state of the standby transmission unit, and the health check by the health check unit It is preferable that the period can be arbitrarily set. When the health check of the standby transmission unit is performed by the health check unit, or when the transmission unit is switched to the standby transmission unit, the power is input in a state where the input level of the power amplifier of the standby transmission unit is minimum. It is preferable to turn on the power of the amplifier and start up the power amplifier.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Next, an embodiment of a transmission unit control method of a wireless communication apparatus according to the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is a diagram for explaining an embodiment of the present invention and is a diagram showing a basic configuration of a wireless communication apparatus (transmission unit). As shown in this figure, the wireless communication device 11 includes a 0-system transmission unit 12, a 1-system transmission unit 13, a monitoring control unit 14, and a switch unit 15.
[0010]
The 0-system transmitter 12 is one of the duplexed transmitters, and receives a 0-system input signal and outputs a 0-system output signal. The 1-system transmitter 13 receives the 1-system input signal and outputs the 1-system output signal in the other one of the duplexed transmitters. Now, when the system that is communicating is called the active system and the system that is not communicating is called the standby system, in the actual operation state, the 0-system transmitter 12 is the active system transmitter, and the 1-system transmitter 13 is There are cases where it is a standby transmission unit, and there are cases where the 0-system transmission unit 12 is a standby transmission unit and the 1-system transmission unit 13 is an active transmission unit.
[0011]
As shown in FIG. 2, the monitoring control unit 14 is supplied with a switching signal from the host device 16. The host device 16 has a configuration different from that of the wireless communication device 11. When the host device 16 detects a decrease in the level of the RF output signal output from the wireless communication device 11 and detects that a failure has occurred in the transmitter (active transmitter), the host device 16 generates the switching signal. The host device 16 outputs the switching signal at the health check of the standby transmission unit. The health check is an operation for checking the operating state of the standby transmission unit, and the cycle for executing the health check has a timer by software that operates the CPU 161 built in the host device 16, and can be arbitrarily set by the timer. It is.
[0012]
The monitoring controller 14 outputs a 0-system PA control signal for controlling the power supply of the power amplifier in the 0-system transmitter 12 to the 0-system transmitter 12. From the 0-system transmission unit 12, a 0-system output level monitor signal indicating the level of the output signal from the 0-system transmission unit 12 is output to the monitoring control unit 14. Similarly, the monitoring controller 14 outputs a 1-system PA control signal for controlling the power supply of the power amplifier in the 1-system transmitter 13 to the 1-system transmitter 13. From the 1-system transmitter 13, a 1-system output level monitor signal indicating the level of the output signal from the 1-system transmitter 13 is output to the monitoring controller 14.
[0013]
In addition, the monitoring control unit 14 outputs a switch switching signal to the switch unit 15. The switch unit 15 receives this switch switching signal and switches the RF output signal between the 0-system transmission unit 12 and the 1-system transmission unit 13.
[0014]
In the wireless communication apparatus 11 as described above, it is assumed that the 0-system transmission unit 12 is set as the active system transmission unit and the 1-system transmission unit 13 is set as the standby system transmission unit. In this state, the switching signal is set to the 0 system, and the 0 system PA control signal output from the monitoring controller 14 is output as an ON signal. As a result, the power supply of the power amplifier of the 0-system transmission unit 12 is turned on, the power amplifier enters an operating state, and a 0-system output signal is output.
[0015]
On the other hand, the 1-system PA control signal is output as an OFF signal, whereby the power of the power amplifier of the 1-system transmitter 13 is turned off, no power is supplied to the power amplifier, and the power amplifier amplifies the signal. Not performed. Therefore, the 1-system output signal is no signal.
[0016]
The switch unit 15 is set to 0 system by the switch switching signal output from the monitoring control unit 14, and outputs the 0 system output signal from the 0 system transmission unit 12 as an RF output signal of the wireless communication device 11.
[0017]
Next, the transmission unit switching operation (system switching operation) when a failure occurs will be described. Here, a case where the 0-system transmission unit 12 is switched to the standby system and the 1-system transmission unit 13 is switched to the active system will be described.
[0018]
When the host device 16 detects a decrease in the level of the RF output signal output from the wireless communication device 11, and the host device 16 detects the occurrence of a failure in the active transmission unit (system 0 transmission unit 12), the switching signal System switching is performed, and start-up operation of the standby system transmission unit (system 1 transmission unit 13) is started. That is, a switching signal is generated, the switching signal designates the first system, and the monitoring control unit 14 sets the first system PA control signal for the first system transmission unit 13 to the ON signal. Then, the power of the power amplifier of the 1-system transmitter 13 is turned on, the power amplifier is in an operating state, and a 1-system output signal is output. The monitoring control unit 14 monitors the 1-system output level monitor signal indicating the level of the 1-system output signal output from the 1-system transmission unit 13, and the monitor signal level (that is, the 1-system output signal level) is set in advance. When it is confirmed that the value is within the upper limit value and the lower limit value, a switch switching signal is output to the switch unit 15 after a predetermined time elapses to instruct switching from the 0 system to the 1 system. Based on this switching instruction, the switch unit 15 switches the RF output signal from the 0-system transmission unit 12 to the 1-system transmission unit 13 and outputs it.
[0019]
When the switching of the system by the switch unit 15 is completed, the monitoring control unit 14 sets the 0-system PA control signal to an OFF signal. As a result, the power supply of the power amplifier of the 0-system transmitter 12 is turned off, and the power amplifier is not subjected to signal amplification.
[0020]
Thus, according to the above method, the power amplifier of the standby transmission unit that is not normally used turns off the power supply. As a result, the power consumption of the wireless communication device 11 can be reduced. In addition, since the radiator can be made smaller by reducing power consumption, the wireless communication device 11 can be reduced in size and weight. In addition, semiconductor devices generally have a shorter life as the energization time becomes longer. By adopting the above power-off method, the life of the power amplifier (semiconductor device) in the standby transmission unit is extended and the reliability is improved. Can be made.
[0021]
Further, according to the above method, when the system is switched, that is, when the transmission unit is switched from the active transmission unit to the standby transmission unit, the output signal level (output power) of the standby transmission unit falls within a predetermined range and is stabilized. Since the system is switched by the switch unit 15 after that, the output power from the wireless communication apparatus 11 can be stabilized.
[0022]
According to the above apparatus, it is possible to further perform a health check that checks the operating state of the standby transmission unit by turning on the power of the power amplifier of the standby transmission unit. The operation during the health check is described below.
[0023]
When putting the power amplifier of the standby transmission unit into an operating state, it is necessary to periodically check beforehand that there is no abnormality in the power amplifier. The health check has a timer by software that operates the CPU 161 in the host device 16 that controls the wireless communication device, and a cycle can be arbitrarily set by the timer. When the predetermined time of the cycle is reached, a switching signal is generated to activate the standby transmission unit and perform an operation check. Since the start-up operation in this case is the same as the system switching operation described above, detailed description is omitted. In the operation check, the monitor control unit 14 monitors the output level monitor signal obtained from the standby transmission unit, and the output signal level output from the standby transmission unit is lower than the upper limit value and higher than the lower limit value. Make sure. If the output signal level is not within the specified range, the system switching operation is not performed even if the system switching is instructed by the switching signal thereafter. Also, at the time of health check, immediately after the operation check is performed as described above, the power amplifier is turned off by the PA control signal to return the standby transmission unit to the standby state. Therefore, during the health check, the output switching by the switch unit 15 is not performed.
[0024]
Such a health check is carried out periodically, but the cycle for carrying out it can be set arbitrarily and can be carried out every several years. In general, a semiconductor element has a longer life as the energization time is shorter. By extending the period of performing the health check, the reliability of the device can be improved and the service life can be extended.
[0025]
When starting up the power amplifier of the standby transmission unit during such a health check and the above-described system switching operation, if power is supplied to the power amplifier in the presence of signal input, normal ALC (automatic level control) is applied. Since the function of keeping the output level constant is incorporated, the power amplifier becomes over input and stress is applied.
[0026]
In order to avoid this, in the above apparatus, a variable attenuator is inserted in front of the power amplifier, and the variable attenuator is set to the maximum attenuation state in the standby state. Then, when the power is supplied to the power amplifier, the ALC starts to operate. However, since the ALC operates from the state where the input level of the power amplifier is the minimum, it is possible to avoid the stress being applied due to the excessive input of the power amplifier.
[0027]
FIG. 3 is a specific example, and is a configuration diagram showing the wireless communication device 11 of FIG. 1 specifically in the 0-system transmission unit 12 and the 1-system transmission unit 13. As shown in this figure, the 0-system transmission unit 12 and the 1-system transmission unit 13 have the same specific configuration and include a power amplifier 17, an ALC circuit 18, and a power supply control circuit 19.
[0028]
The power amplifier 17 includes a variable attenuator 171, a mixer 172, and a power amplifier 173. An input signal is first input to the variable attenuator 171, then input to the frequency conversion mixer 172, and finally the power amplifier 173. Is input.
[0029]
The ALC circuit 18 detects the output of the power amplifier 173 input via the diode 181 and controls the variable attenuator 171 with the output, whereby the output of the power amplifier 17, that is, the output signal of each of the transmission units 12 and 13. It works to keep the level constant. From the ALC circuit 18, an output level monitor signal indicating the output signal level of each of the transmission units 12 and 13 is supplied to the monitoring control unit 14.
[0030]
The power supply control circuit 19 receives the PA control signal from the monitoring control unit 14 and controls the bias voltage of the power amplifier 173 (power supply of the power amplifier 17). The PA control signal from the monitoring control unit 14 is also supplied to the ALC circuit 18 in order to control the ALC circuit 18.
[0031]
In such a specific example, when the switching signal designates the 0-system transmission unit 12 as the active transmission unit, the monitoring-system control unit 14 outputs the 0-system PA control signal as an ON signal. Then, the power control circuit 19 of the 0-system transmitter 12 outputs a 0-system PA bias voltage to the power amplifier 173 of the 0-system transmitter 12. As a result, the power amplifier 173 of the 0-system transmitter 12, that is, the power amplifier 17 of the 0-system transmitter 12 is activated, and a 0-system output signal is output.
[0032]
In the switch unit 15, the 0-system transmission unit 12 is selected by the switch switching signal from the monitoring control unit 14, and the 0-system output signal from the 0-system transmission unit 12 is output as the RF output signal of the wireless communication device 11.
[0033]
On the other hand, the 1-system PA control signal is output as an OFF signal from the monitoring control unit 14. Then, the 1-system PA bias voltage output from the power supply control circuit 19 of the 1-system transmission unit 13 remains 0 V, and the power amplifier 173 of the 1-system transmission unit 13 becomes inoperative. Therefore, the power amplifier 17 of the 1-system transmission unit 13 does not amplify the signal, and the 1-system transmission unit 13 enters the standby state.
[0034]
FIG. 4 shows a specific example as described above, when the system is switched due to a failure or a maintenance check (excluding health check), the 0-system transmission unit 12 is a standby system transmission unit, and the 1-system transmission unit 13 is an active system transmission unit. The state switched to is shown. FIG. 5 shows a timing chart when the system is switched.
[0035]
The system switching operation in the specific example will be described with reference to FIG. 5. When a failure occurs as shown in FIG. 5 (a) or maintenance inspection starts, the host device as shown in FIG. 5 (b). When 16 detects a failure or maintenance inspection, a switching signal is generated as shown in FIG. 5C to instruct switching from the 0 system to the 1 system. Then, as shown in FIG. 5D, the 1-system PA control signal output from the monitoring controller 14 is turned on. Then, the power supply control circuit 19 of the 1-system transmitter 13 outputs a 1-system PA bias voltage to the power amplifier 173 of the 1-system transmitter 13 as shown in FIG. As a result, the power amplifier 17 of the 1-system transmission unit 13 enters the operating state, and the 1-system transmission unit 13 enters the transmission state, and a 1-system output signal is output as shown in FIG.
[0036]
At the same time, a 1-system output level monitor signal is output from the ALC circuit 18 of the 1-system transmitter 13 as shown in FIG. This signal outputs a voltage proportional to the output signal level of the 1-system transmitter 13. When the monitoring control unit 14 confirms that this voltage, that is, the output signal level of the 1-system transmission unit 13 is within the preset upper limit value and lower limit value, after a predetermined time, as shown in FIG. A switch switching signal is output to instruct system switching from the 0 system to the 1 system.
[0037]
In the switch unit 15, the 1-system transmission unit 13 is selected by the switch switching signal from the monitoring control unit 14, and the output signal of the 1-system transmission unit 13 is output to the RF output of the wireless communication device 11 as shown in FIG. Output as a signal.
[0038]
After executing the output switching in this way, the 0-system PA control signal output from the monitoring control unit 14 is set to the OFF state as shown in FIG. Therefore, the 0-system PA bias voltage output from the power supply control circuit 19 of the 0-system transmitter 12 is 0 V as shown in FIG. As a result, the power amplifier 173 of the 0-system transmitter 12, that is, the power amplifier 17 of the 0-system transmitter 12, is deactivated, and the 0-system transmitter 12 does not output a signal as shown in FIG. It becomes a state.
[0039]
When performing a health check, start up the standby transmission unit in the same way as the system switching operation described above, and check that the output level monitor signal is within the preset upper and lower limits. Check. After confirmation, a sequence for returning the started transmission unit to the above-described standby state is executed. When the health check is executed, no switch switching signal is generated, and the output state from the active transmission unit is maintained.
[0040]
As a method for preventing surge stress from being applied when starting up the power amplifier of the standby transmission unit, in the specific example of FIG. 4, the power amplifier 17 in the standby state is a variable attenuator inserted in the first stage. 171 is set to the maximum attenuation state. By starting the startup operation from this state, it is possible to prevent stress from being applied due to excessive input. The variable attenuator 171 receives the PA control signal and is controlled by the ALC circuit 18, so that the variable attenuator 171 can be in the maximum attenuation state at the time of startup.
[0041]
In the above-described embodiment and specific example, the occurrence of a failure is detected by the higher-level device 16 having a configuration different from that of the wireless communication device 11. However, in this case, the processing in the higher-level device 16 illustrated in FIG. System switching is delayed by time t. On the other hand, a decrease in the output signal level of the transmission unit, that is, the occurrence of a failure can be detected by the output level monitor signal output from the ALC circuit 18 of the transmission unit. If fault detection and generation of a switching signal are executed in the communication device 11, system switching can be accelerated by the processing time t of the host device 16.
[0042]
【The invention's effect】
As described above in detail, according to the transmission unit control method of the wireless communication apparatus of the present invention, the power amplifier of the standby transmission unit that is not normally used is set to the off state. The power consumption of the device can be reduced, and the radiator can be made smaller by reducing the power consumption. Therefore, the wireless communication device can be reduced in size and weight. In addition, semiconductor devices generally have a shorter life as the energization time becomes longer. By adopting the above power-off method, the life of the power amplifier (semiconductor device) in the standby transmission unit is extended and the reliability is improved. It can also be made.
[Brief description of the drawings]
FIG. 1 is a diagram for illustrating an embodiment of the present invention and illustrating a basic configuration of a wireless communication apparatus.
FIG. 2 is a diagram illustrating a state in which a switching signal is supplied from a host device to a wireless communication device.
FIG. 3 is a diagram specifically showing the inside of a transmission unit and showing the wireless communication apparatus of FIG. 1;
4 is a diagram showing the wireless communication apparatus of FIG. 3 in a state where the 0-system transmission unit is switched to the standby transmission unit and the 1-system transmission unit is switched to the active transmission unit.
5 is a timing chart when system switching is performed from the state of FIG. 3 to the state of FIG. 4;
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 11 Wireless communication apparatus 12 0 system transmission part 13 1 system transmission part 14 Monitoring control part 15 Switch part 16 Host apparatus 17 Power amplifier 171 Variable attenuator 173 Power amplifier 18 ALC circuit 19 Power supply control circuit

Claims (6)

In a wireless communication apparatus including an active transmission unit that is in a communication state and a standby transmission unit that is not performing communication,
A method for controlling a transmitter of a wireless communication apparatus, comprising: means for turning off a power of a power amplifier of a transmitter, wherein the power of the power amplifier of the standby transmitter is set to an off state by the power off means . When a failure occurs in the active transmission unit, means for detecting it and generating a switching signal;
When a switching signal is generated by this means, means for turning on the power of the power amplifier of the standby transmission unit;
Means for switching the high-frequency output to the standby transmission unit side in which the power amplifier is turned on and is in an operating state by the power-on means;
2. The apparatus according to claim 1, further comprising means for turning off the power of the power amplifier of the active transmission unit when the high frequency output is switched to the standby transmission unit by the switching unit. The transmission part control method of the radio | wireless communication apparatus of description. The high-frequency output level of the standby transmission unit in an operating state is monitored, and when the high-frequency output level falls within a predetermined range, the high-frequency output is switched to the standby transmission unit side by the switching means. The transmission unit control method for a wireless communication apparatus according to claim 2. The detection of a failure that has occurred in the active transmission unit and the generation of a switching signal are performed in the wireless communication device using a signal from a circuit in the active transmission unit. The transmission part control method of the wireless communication apparatus of description. It has health check means for checking the operating state of the standby transmission section by turning on the power of the power amplifier of the standby transmission section, and the period of health check by the health check means can be arbitrarily set The transmission part control method of the radio | wireless communication apparatus of Claim 1. When switching the transmission unit to the standby transmission unit or performing a health check of the standby transmission unit, the power amplifier is turned on with the input level of the power amplifier of the standby transmission unit being at a minimum level. 6. The method of controlling a transmitter of a wireless communication apparatus according to claim 2, wherein the power amplifier is started up.

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