JP2004032447A - Transmitter in radio device and transmission level control method therefor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To carry out normal gain control for a signal outside the scope of the dynamic range of a detecting section. <P>SOLUTION: A transmitter in this radio device comprises a transmitting section 1, a transmitting power amplifying section (TXAMP) 13, and an antenna (ANT) 14. The transmitting section 1 has a BB section 2 for receiving baseband information (BB information) 3 from outside and outputting a baseband signal (BB signal) 4, an RF section 20 for converting the BB signal 4 into a frequency of a carrier of a predetermined channel and for sending it out as an RF signal 9, an A/D section 10 for detecting the RF signal 9 from the RF section 20 and converting it into a digital signal by A/D conversion and sending it out, a D/A section 12 for carrying out the D/A conversion of the digital signal from the A/D section 10 to send out a signal for making the amplification of the BB signal in the RF section 20 variable, and a control unit 11 for controlling the RF section 20 and the TXAMP 13 based on the digital signal from the A/D section 10. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a transmitter of a wireless device and a transmission level control method thereof, and more particularly, to accurately control transmission power based on a detection value of a transmission signal detected by a detector in a CDMA (Code Division Multiple Access) type mobile communication system. The present invention relates to a transmitter of a wireless device and a transmission level control method thereof.
[0002]
[Prior art]
This type of related art will be described with reference to the drawings.
[0003]
8 is a block diagram illustrating an example of a transmitter of the conventional wireless device, FIG. 9 is a block diagram illustrating a configuration of a feedback amount generation unit in the transmitter of the conventional wireless device illustrated in FIG. 8, and FIG. 10 is illustrated in FIG. 5 is a flowchart illustrating an operation of a feedback amount generation unit.
[0004]
Next, control of the transmission power of the transmitter of the conventional wireless device will be described with reference to FIGS.
[0005]
The control of the transmission power of the transmitter of the conventional example described below shows the contents disclosed in the "second embodiment" of Japanese Patent Laid-Open No. 11-308126.
[0006]
In this conventional example, in FIG. 8, when the input signal to the detector 119 is sufficiently large and within a signal detectable range, a valid detection signal is obtained as a detection value D2 output from the detector 119. Therefore, as in the first embodiment, the transmission power is adjusted so that a predetermined transmission power is obtained by feedback control in which a feedback amount H2 based on the transmission power error E2 is generated and fed back to the variable gain circuit 112. be able to. However, when performing transmission power control corresponding to a wide dynamic range, it is conceivable that an input signal to the detector 119 is small and falls below a signal detectable range. In this case, since the transmission power adjustment effect by the feedback control is lost, it is necessary to return the feedback amount H2 to the initial state. This is to make it possible to smoothly shift to the transmission power adjustment operation by the feedback control when the power is again within the power detection range, and to prevent a problem from occurring even if the operating conditions such as the ambient temperature change.
[0007]
As shown in FIGS. 9 and 10, in the feedback amount generation unit 130, the feedback correction value F2 from the loop gain multiplication unit 122 is input to the power detection range operation unit 131 (step S11), and the selector 133 is input to the selector 133. The transmission power designation information A2 is input from the transmission power designation unit 16, and it is determined whether or not the transmission power is within the power detection range based on the output power value to be transmitted (step S12). If it is within the power detection range, the feedback correction value F2 input by the power detection range operation unit 131 is added and stored in the data storage unit 135 (step S13), and the selector 133 operates in the power detection range. The output of the unit 131 is selected and output as the feedback amount H2 (step S14). In the initial state, the data holding unit 135 is reset by a reset signal.
[0008]
On the other hand, if it is determined in step S12 that the value is outside the power detection range, the power detection range operation unit 132 subtracts the subtraction amount stored in the subtraction amount storage unit 137 from the value stored in the data storage unit 135. Then (step S15), the selector 133 selects the output of the operation unit 132 outside the power detection range and outputs it as the feedback amount H2 (step S14).
[0009]
As described above, in this conventional example, by repeating the feedback amount generation processing (steps S11 to S15), the feedback amount H2 held in the data holding unit 135 is gradually subtracted outside the power detection range to return to the initial state. Approaching. At this time, transmission power control is performed such that the power variable amount per control step falls within the allowable range of the power variable amount accuracy.
[0010]
[Problems to be solved by the invention]
The transmitter and the transmission level control method of this conventional wireless device are designed such that, outside the power range of the detector, the feedback amount held in the data holding unit is gradually subtracted and returned to the initial state, so that the detection range is reduced. There is a problem that a difference in the amount of feedback occurs between inside and outside, and discontinuous control is performed, so that transmission power cannot be controlled with high accuracy.
[0011]
(Object of the invention)
SUMMARY OF THE INVENTION It is an object of the present invention to provide a transmitter of a radio apparatus and a transmission level control method thereof that can accurately control a transmission signal outside a dynamic range of a detection circuit in initial operation control.
[0012]
[Means for Solving the Problems]
The transmitter of the wireless device according to the present invention is a transmitter used for a base station wireless device, wherein the transmitter receives a multiplexed baseband information and sends out a frequency-modulated RF signal. A transmission power amplification unit connected to the transmission unit for power amplification of the RF signal, and an antenna connected to the transmission power amplification unit and transmitting the power-amplified RF signal to the air, the transmission unit includes: A baseband unit that receives the baseband information and sends a baseband signal; an RF unit that sends the RF signal variably amplified after frequency modulation of the baseband signal to the transmission power amplifying unit; An A / D unit for A / D converting a detected RF signal obtained by detecting the RF signal from the A / D unit, and a D / A unit for transmitting the variable amplification control signal to the RF unit by the D / A converted signal. When it is determined that the level of the baseband signal is within a preset control level reference value at the time of the initial operation, after transmitting the control signal via the D / A unit to reduce the attenuation to a preset lower limit, A control unit for transmitting the control signal to the RF unit via the D / A unit so as to reduce the preset attenuation in a step-by-step manner to a preset upper limit attenuation. A mixer for modulating the baseband signal to a predetermined frequency, an amplifying unit for amplifying the modulated signal and turning on / off the power by the control unit; A variable attenuator that variably attenuates an output signal based on a control signal from the control unit and sends the RF signal to the transmission power amplifying unit; a coupler that detects the RF signal; A detection unit for detecting the detected detection RF signal and transmitting the detected detection RF signal to the A / D unit, wherein the baseband signal is output when the baseband signal exceeds the upper limit variable amplification factor of the control level reference value. A pseudo baseband signal generation unit for generating a pseudo baseband signal having a preset amplification level used for controlling the variable attenuator when the baseband signal is detected, and a baseband for detecting the level of the baseband signal A signal level detection unit, wherein the control unit stores a memory storing the upper limit variable amplification factor and a lower limit variable amplification factor of the control level reference value, and a predetermined value of the variable attenuator at an initial operation. An initial value storage unit that stores the initial attenuation degree, and an output level of a baseband signal from the baseband level detection unit that is equal to the control level reference value. A determination unit for determining whether the signal is within the range, a comparison unit for comparing the output level of the baseband signal with the detected RF signal from the A / D unit, and After the initial attenuation is transmitted to the variable attenuator in the RF unit via the D / A unit and set to the initial attenuation, the initial attenuation is set in a stepwise manner for each of the preset periods based on the comparison result of the comparison unit. A power control unit that controls the variable attenuator by transmitting the control signal via the D / A unit to reduce a preset attenuation to a preset upper limit variable attenuation; And a transmission control unit for controlling ON / OFF of a power supply to the transmission power amplification unit.
[0013]
A transmission level control method for a transmitter of a wireless device according to the present invention is a transmitter used for a base station wireless device, wherein the transmitter receives multiplexed baseband information and converts a frequency-modulated RF signal. A transmission unit for transmitting, a transmission power amplification unit connected to the transmission unit for power amplification of the RF signal, and an antenna connected to the transmission power amplification unit and transmitting the power-amplified RF signal to the air A transmission unit configured to receive the baseband information and transmit a baseband signal; and an RF unit configured to frequency-modulate the baseband signal and transmit the RF signal variably amplified to the transmission power amplification unit. An A / D unit for A / D converting a detected RF signal obtained by detecting the RF signal from the RF unit; and a control signal for the variable amplification to the RF unit by the D / A converted signal. A D / A unit for transmitting, an amplifying unit for amplifying the baseband signal after frequency modulation in the RF unit, and a variable attenuator for variably attenuating the amplified signal and transmitting the amplified signal as the RF signal to the transmission power amplifying unit The control unit determines whether or not the level of the baseband signal is within a preset control level reference value at the time of initial operation. The power of the amplifying unit and the transmission power amplifying unit is turned on after setting the minimum attenuation level which is set in advance as an initial value for the variable attenuator, and then the initial value is set to the starting value for the variable attenuator. Setting a step attenuation level preset in a stepwise manner for each preset period, and then setting a final attenuation level preset for the variable attenuator; After confirming that the level of the baseband is within the control level reference value, the control unit starts a second control operation that is set next to the initial operation and the control unit performs the second control operation. Upon entering, first, the baseband signal is read from the baseband unit and the detected RF signal from the RF unit via the A / D unit, and then the level of the baseband signal falls within the control level reference value. It is determined whether there is, and if it is within the reference value, the detected RF signal is compared with the level of the baseband signal. If the detected RF signal is larger than the baseband signal, the current variable attenuation is determined. Lower than the attenuation level of the variable attenuator by a predetermined attenuation level, and if smaller than the current attenuation level of the variable attenuator by the predetermined attenuation level. The control unit controls the detected RF signal to be close to the level of the baseband signal, and the control unit controls the level of the baseband signal during the initial operation to be outside the preset control level reference value. When it is determined, the attenuation level with the variable attenuator is set to 0 dB, the power is turned on to the amplifying unit, the initial operation is set, and a pseudo-baseband signal whose level is set in advance from the baseband unit is read. Next, the detection RF signal is read from an RF unit, and then the level of the pseudo baseband signal is compared with the level of the detection RF signal, and the level of the detection RF signal is higher than the level of the pseudo baseband signal. If it is large, decrease the attenuation level of the variable attenuator.If it is small, increase the attenuation level. Decrease or increase the attenuation level. After setting the attenuation level of said variable attenuator performs preset number of times the number, and controls at the initial operation after the power supply of the amplifying unit to OFF.
[0014]
BEST MODE FOR CARRYING OUT THE INVENTION
Next, the present invention will be described with reference to the drawings.
[0015]
FIG. 1 is a block diagram illustrating a transmitter of a wireless device according to an embodiment of the present invention, and FIG. 2 is a block diagram illustrating a BB unit and a control unit in the transmitter according to the embodiment.
[0016]
In FIG. 1, a transmitter of a wireless device according to an embodiment of the present invention transmits an RF signal 9 frequency-modulated by a transmitter used for a base station wireless device of a mobile communication system using a CDMA system. A transmission unit 1, a transmission power amplification unit (TXAMP) 13 connected to the transmission unit 1 for power amplification of the RF signal 9, an antenna (AMT) 14 connected to the TXAMP 13 and transmitting the power amplified RF signal 9 in the air, Is configured. The transmitting unit 1 receives a baseband information (BB information) 3 from the outside and outputs a baseband signal (BB signal) 4 to the BB unit 2 and a BB signal 4 by a carrier of a predetermined channel. An RF unit 20 that transmits the RF signal 9 to the TXAMP 13 after being converted to a certain frequency, an A / D unit 10 that detects the RF signal 9 from the RF unit 20 and transmits an A / D-converted digital signal; A D / A unit 12 for converting a digital signal from the D unit 10 into a digital signal and transmitting a signal for varying the amplification of the BB signal 4 in the RF unit 20; And a control unit 11 for controlling the TXAMP 13.
[0017]
The RF unit 20 includes a mixer 5 that modulates a baseband signal to a predetermined frequency, an amplifying unit (TX) 6 that amplifies the modulated signal and whose power is on / off controlled by a control unit 11, and an amplifying unit. A variable attenuator 7 for variably attenuating the output signal of the (TX) 6 based on a control signal from the control unit 11 and transmitting the RF signal 9 to a transmission power amplifying unit (TXAMP) 13; and a coupler for detecting the RF signal 9 And a detector 15 for detecting the detected RF signal detected by the coupler 8 and transmitting the detected RF signal to the A / D unit 10.
[0018]
2, BB section 2 in transmitting section 1 according to the present embodiment includes BB level detecting section 2a for detecting the level of BB signal 4 from BB information 3, and a pseudo-BB signal for generating a predetermined pseudo-BB signal of 34 dBm. The BB signal generation unit 2b includes a control unit 11 that sets a predetermined maximum (43 dBm) and minimum (25 dBm) of the level (BB) of the BB signal 4 corresponding to the output of the RF signal 9 from the transmitter 1. An Automatic Level Control (ALC) range determination unit that determines whether the stored memory 11b and the level BB of the BB signal 4 from the BB level detection unit 2a are within 25 (dBm) ≦ BB ≦ 43 (dBm). 11a and an initial variable attenuator 7 for setting the level of the BB signal 4 corresponding to the initial RF signal 9 (Gagc) set value (Gagc) agc = −18 dB) and a signal (RF) A / D converted by the A / D unit 10 after the detection unit 15 detects the detection signal obtained by detecting the RF signal 9 by the coupler 8, and Signal) and a determination signal (BB signal) determined by the ALC range determination unit 11a, and an amplification unit (TX) 6 based on the determination signal (BB signal) of the ALC range determination unit 11a. And a transmission control unit 11g for controlling ON / OFF of power to the TXAMP, a switch 11f for switching between initial and transmission or during transmission power control, and a BB signal of the power comparison unit 11d during transmission or transmission power control. And a power control unit 11e that controls the transmission power of the RF signal by changing the variable attenuator 7 via the switch 11f and the D / A unit 12 based on the comparison between the RF signal and the RF signal.
[0019]
FIG. 3 is a diagram showing the time-output characteristics of the variable attenuator in the transmitter according to the present embodiment, and FIG. 4 is a diagram showing the time of the variable attenuator when the input level to the detector is out of its dynamic range in the present embodiment. FIG. 5 is a flowchart showing an output characteristic, FIG. 5 is a flowchart showing an initial control operation of a control unit in a transmission unit in the present embodiment, and FIG. 6 is a flowchart showing a control operation of the control unit in an automatic gain control (ALC) state in FIG. FIG. 7 is a flowchart showing the operation of the control unit when the input level to the detection unit is out of the dynamic range in the present embodiment.
[0020]
Next, the operation of the transmitter according to the present embodiment will be described with reference to FIGS.
[0021]
First, the initial operation will be described based on FIG. 5 with reference to FIGS.
[0022]
In the transmitter of the present embodiment, ALC control in which the signal level BB of the BB signal is set in advance for the BB signal 4 of the input signal so that the RF signal 9 of the output signal does not exceed the dynamic range of the detection unit 15 This is a system for monitoring so that 25 (dBm) ≦ BB ≦ 43 (dBm), which determines whether or not an input is made.
[0023]
In view of this, the memory 11b in the control unit 11 stores the judgment of whether to enter the control of the ALC with a minimum value of 25 dBm and a maximum value of 43 dBm for the BB signal set in advance. In the initial ALC unit 11c, Gagc = −18 dB is stored in advance as an initial attenuation value for the variable attenuator 7.
[0024]
First, Step A1: When the transmitting unit 1 starts the initial control operation,
Step A2: The ALC range determination unit 11a determines whether the level BB of the multiplexed BB signal 4 received and multiplexed by the BB unit 2 from the BB level detection unit 2a is within the ALC range.
[0025]
Next, Step A3: If the level BB of the BB signal 4 is in the ALC range, the power control unit 11e switches the input of the switch 11f to the initial ALG unit 11c side, and sets the attenuation of the variable attenuator 7 to Gagc = − It is set to 18 dB (see FIG. 3).
[0026]
Next, Step A4: The power of the amplification unit 6 and the TXAMP 13 is turned on under the control of the transmission control unit 11g to start amplification. (TXON, TXAMPON)
Next, Steps A5 to A6: For smooth start-up (gradual rise), the attenuation (Gagc) of the variable attenuator 7 is increased by 1 dB at intervals of 200 ms (see FIG. 3).
[0027]
Next, Step A7: Under the control of the power control unit 11e, the method of linearly increasing Gagc is performed stepwise up to -3dB (see FIG. 3).
[0028]
Next, step A8: The ALC range determination unit 11a determines again whether the level BB of the BB signal 4 is within the ALC range.
[0029]
Next, ALC is started when it is within the ALC range in step A10: A8. (Becomes ALCON state)
The above is the method of the initial control of the transmission unit 1.
[0030]
Next, a method of controlling the ALC after the end of the initial operation of the gradually increasing operation will be described with reference to FIG.
[0031]
Step B1: When the control operation of ALC starts,
Next, Step B2: The level of the RF signal 8 detected by the detection unit 15 and A / D converted by the A / D unit 10 is input to the power comparison unit 11d, and the level B from the BB level detection unit 2a is used as an ALC range determination unit. 11a.
[0032]
Next, Step B3: It is determined whether the level BB of the BB signal 4 is within the ALC range.
[0033]
Next, in step B4: when the current is within the ALC range in B3, the level BB of the RF signal 9 and the level BB of the BB signal 4 are compared by the power comparing unit 11d.
[0034]
Next, Steps B5 and B6: If RF ≧ BB, decrease Gagc by 0.05 dB, and if RF <BB, increase Gagc by 0.05 dB.
[0035]
The control operation of the ALC is activated by going around the loop (B) of steps B2 to B6.
[0036]
FIG. 3 shows the characteristics of the operations of steps A1 to A10 and steps B1 to B6 on the horizontal axis / time and the vertical axis / level. The purpose of ALC is to correct the frequency deviation, temperature deviation, etc., and to automatically keep the gain of the transmitting unit 1 constant. The amount of attenuation of the variable attenuator 7 depends on the input BB level. And is designed to keep Gagc = 0 dB, but this is not guaranteed. Therefore, if the gain is increased to 0 dB in step A7, the transmitting unit 1 becomes over-output due to the influence of the variation of the amplifier 6, overloads the TXAMP 13 in the subsequent stage, and further increases interference on the air through the ANT 14. It will be. Therefore, the control of the ALC is a meaningful control for preventing the over-output by mechanically starting up to a level lower than Gagc = 0 dB and then performing accurate gain correction by the ALC.
[0037]
Next, control when the level BB of the BB signal 4 is out of the ALC range at the start of the initial control will be described with reference to FIGS.
[0038]
First, in step A of FIG. 5, the ALC range determination unit 11a determines whether the level BB of the BB signal 4 from the BB level detection unit 2a is within the ALC range. If the level BB is outside the range, the process proceeds to the flowchart C1 of FIG.
[0039]
Next, Step C2: The power control unit 11e receives the determination result of the ALC range determination unit 11a, and controls the variable attenuator 7 via the switch 11f so that Gagc = 0 dB.
[0040]
Next, Step C3: Only the amplification unit 6 is turned on to start amplification. (TXON)
Next, Step C4: ALC operation is started. (ALCON)
Next, Step C5: The pseudo BB signal 4 is output from the pseudo BB signal generator 2b of the judgment result BB unit 2 of the ALC range judging unit 11a in a preset 34 dBm RF signal level conversion.
[0041]
Next, Step C6: The level of the pseudo BB signal 4 is detected by the detection unit 15 and input to the level power comparison unit 11d of the RF signal 8 that has been A / D converted by the A / D unit 10.
[0042]
Next, Step C7: The level of the RF signal 8 and the level of the pseudo BB signal 4 are compared by the power comparing unit 11d.
[0043]
Next, Steps C8 and C9: If RF ≧ pseudo BB, decrease Gagc by 0.05 dB, and if RF <pseudo BB, increase Gagc by 0.05 dB.
[0044]
Next, steps C10 and C11: ALC operations from C6 to C9 are repeated until Gagc converges (20 times in this case). Since 20 times x 0.05 dB = 1 dB, Gagc can be corrected within ± 1 dB. (Ex. Gagc = −1 dB because of frequency and temperature deviations.) (The number of times is controlled by the power control unit 11e.)
Next, step C12: X = Gagc (dB) = ± 0.05 × x, (x = 20). (Ex. X = -1 dB)
C13: Under the control of the transmission control unit 11g, the power of the amplification unit 6 is turned off to stop amplification. (TXOFF)
Thereafter, the flow returns to the flowchart A3 in FIG.
[0045]
That is, steps A4 to A7: Gradually increasing to Gagc = -3 dB shown in FIG.
[0046]
Next, Step A8: It is determined whether the level BB of the BB signal 4 is within the ALC range.
[0047]
Next, Steps A9 and A10: Gagc = XdB when out of the ALC range. (Ex. Control up to Gagc = -1 dB)
Thereafter, the operation shifts to the control operation of the ALC flowchart of FIG.
[0048]
That is, Step B2: The level BB of the BB signal 4 and the level of the RF signal 9 detected by the detection unit 15 and A / D converted by the A / D unit 10 are input to the power comparison unit 11d. (BB: 24 dBm, RF: 24 dBm)
Next, Step B3: It is determined whether the level BB of the BB signal 4 is within the ALC range.
[0049]
Since it is outside the range, ALC is stopped by going around the loop (A).
[0050]
As in the above example, when the attenuation Gagc = -1 dB of the variable attenuator 7 due to the influence of the frequency deviation and the temperature deviation of the amplifier 6, the gains of the BB signal 4 and the RF signal 15 become constant, and the horizontal axis / time and the vertical axis • The characteristics obtained at the level are as shown in FIG. As described above, in the present embodiment, the gains of the BB signal 4 and the RF signal 9 can be kept constant even outside the ALC range (ALC stop state).
[0051]
【The invention's effect】
As described above, the present invention relates to a transmitter used for a base station radio apparatus, wherein the transmitter receives a multiplexed baseband information and transmits a frequency-modulated RF signal; A transmission power amplifying unit connected to the transmitting unit and amplifying the RF signal; and an antenna connected to the transmitting power amplifying unit and transmitting the power-amplified RF signal to the air. The transmitting unit receives the baseband information and transmits the baseband information. A baseband section for transmitting a signal, an RF section for variably amplifying the baseband signal and then transmitting an RF signal to a transmission power amplifying section, and A / D conversion of a detected RF signal obtained by detecting the RF signal from the RF section A / D unit for transmitting a variable amplification control signal to the RF unit based on the D / A-converted signal, and a control unit in which the level of the baseband signal is set in advance during the initial operation. When the control signal is determined to be within the reference level, a control signal is transmitted through the D / A unit to reduce the attenuation to a preset lower limit. By providing a control unit for transmitting a control signal to the RF unit via the D / A unit in order to achieve a preset upper limit of attenuation, the following effects are obtained.
[0052]
That is, when the baseband signal is inputted outside the preset control level reference value at the time of the initial operation, a pseudo baseband signal is generated, and the detected RF signal is set in the RF unit so as to be within the control level reference value. Since the amplification of the baseband signal is controlled after setting the attenuation of the variable attenuator, the RF signal can be transmitted with high accuracy.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a transmitter of a wireless device according to an embodiment of the present invention.
FIG. 2 is a block diagram illustrating a BB unit and a control unit in a transmission unit according to the present embodiment.
FIG. 3 is a diagram showing time-output characteristics of a variable attenuator in a transmitter according to the present embodiment.
FIG. 4 is a diagram illustrating a time-output characteristic of the variable attenuator when an input level to a detection unit according to the present embodiment is out of a dynamic range.
FIG. 5 is a flowchart illustrating an initial control operation of a control unit in the transmission unit according to the present embodiment.
FIG. 6 is a flowchart showing a control operation of a control unit in an automatic gain control (ALC) state in FIG. 5;
FIG. 7 is a flowchart showing the operation of the control unit when the input level to the detection unit is out of the dynamic range according to the present embodiment.
FIG. 8 is a block diagram illustrating an example of a transmitter of a conventional wireless device.
9 is a block diagram illustrating a configuration of a feedback amount generation unit in a transmitter of the conventional wireless device illustrated in FIG.
10 is a flowchart showing the operation of the feedback amount generator shown in FIG.
[Explanation of symbols]
Reference Signs List 1 transmitting section 2 BB section 2a BB level detecting section 2b pseudo BB signal generating section 3 baseband information (BB information)
4 Baseband signal (BB signal)
5 Mixer 6 Amplifier (TX)
7 Variable attenuator 8 Coupler 9 RF signal 10 A / D unit 11 Control unit 11a ALC range determination unit 11b Memory 11c Initial ALC unit 11d Power comparison unit 11e Power control unit 11f Switch 11g Transmission control unit 12 D / A unit 13 Transmission power Amplifier (TXAMP)
14 Antenna (ANT)
15 Detection unit 20 RF unit

Claims (7)

A transmitter for use in a base station radio apparatus, wherein the transmitter receives multiplexed baseband information and sends out a frequency-modulated RF signal, and the RF signal connected to the transmitter. A transmission power amplifying unit for amplifying the power, and an antenna connected to the transmission power amplifying unit and transmitting the power-amplified RF signal to the air, wherein the transmission unit receives the baseband information and transmits a baseband signal. A baseband unit for transmitting a signal, an RF unit for transmitting the RF signal variably amplified after frequency-modulating the baseband signal to the transmission power amplifying unit, and a detected RF signal for detecting the RF signal from the RF unit An A / D unit for A / D converting the A / D converter, a D / A unit for transmitting the variable amplification control signal to the RF unit based on the D / A converted signal, If it is determined that the signal level is within the preset control level reference value, the control signal is transmitted via the D / A unit to reduce the attenuation to the preset lower limit, and the signal is transmitted at preset intervals. And a control unit for transmitting the control signal to the RF unit via the D / A unit so as to reduce the preset attenuation in a stepwise manner to reach a preset upper limit attenuation. Equipment transmitter. A mixer for modulating the baseband signal to a predetermined frequency; an amplifier for amplifying the modulated signal and power ON / OFF controlled by the controller; and an output of the amplifier. A variable attenuator that variably attenuates a signal based on a control signal from the control unit and sends the RF signal to the transmission power amplifying unit; a coupler that detects the RF signal; and a detection RF signal that is detected by the coupler. 2. The transmitter according to claim 1, further comprising a detection unit that detects a signal and sends the signal to the A / D unit. The baseband unit is configured to simulate a preset amplification level used for controlling a variable attenuator when the baseband signal is equal to or higher than the upper limit variable amplification of the control level reference value. The transmitter for a wireless device according to claim 1, further comprising: a pseudo baseband signal generator that generates a baseband signal; and a baseband signal level detector that detects a level of the baseband signal. The control unit stores a memory storing the upper limit variable amplification factor and a lower limit variable amplification factor of the control level reference value, and stores a predetermined initial attenuation factor of the variable attenuator at an initial operation. An initial value storage unit, a determination unit for determining whether an output level of the baseband signal from the baseband level detection unit is within the control level reference value, and an output level of the baseband signal and the A / D A comparing unit that compares the detected RF signal from the unit with the detected RF signal, and transmitting the initial attenuation degree from the initial value storage unit to the variable attenuator in the RF unit via the D / A unit during an initial operation. After the initial attenuation is set, the predetermined attenuation should be reduced stepwise for each of the preset periods based on the comparison result of the comparison unit to reach a preset upper limit variable attenuation. A power control unit for transmitting the control signal via the D / A unit to control the variable attenuator, and a transmission control unit for controlling ON / OFF of power to the amplification unit and the transmission power amplification unit The transmitter for a wireless device according to claim 1, comprising: A transmitter for use in a base station radio apparatus, wherein the transmitter receives multiplexed baseband information and sends out a frequency-modulated RF signal, and the RF signal connected to the transmitter. A transmission power amplifying unit for amplifying the power, and an antenna connected to the transmission power amplifying unit and transmitting the power-amplified RF signal to the air, wherein the transmission unit receives the baseband information and transmits a baseband signal. A baseband unit for transmitting a signal, an RF unit for transmitting the RF signal variably amplified after frequency-modulating the baseband signal to the transmission power amplifying unit, and a detected RF signal for detecting the RF signal from the RF unit An A / D unit for A / D converting the signal, a D / A unit for transmitting the control signal of the variable amplification to the RF unit based on the D / A converted signal, and the base bar in the RF unit. An amplification unit that amplifies the frequency-modulated signal after amplification, and a variable attenuator that variably attenuates the amplified signal and sends the amplified signal to the transmission power amplification unit as the RF signal. It is determined whether the level of the baseband signal is within a preset control level reference value, and if it is determined that the level is within the reference value, the minimum attenuation preset as an initial value for the variable attenuator is determined. After setting the power to the level, turning on the power of the amplifying unit and the transmission power amplifying unit, and then stepwise presetting the variable attenuator step by step at predetermined intervals starting from the initial value. An attenuation level is set, and then a final attenuation level set in advance for the variable attenuator is set, and the level of the baseband from the baseband section is set to the control level. After confirming that it is in the Le reference value, the transmission level control method of a transmitter of a radio device, characterized in that to start the next preset second control operation of the initial operation. When the control unit enters the second control operation, the control unit first reads the baseband signal from the baseband unit and the detected RF signal from the RF unit via the A / D unit. Determining whether the level of the signal is within the control level reference value, and if the signal level is within the reference value, comparing the detected RF signal with the level of the baseband signal; If the signal is larger than the signal, the current attenuation level of the variable attenuator is decreased by a predetermined attenuation level. If the signal is smaller, the current attenuation level of the variable attenuator is increased by the predetermined attenuation level. 7. The transmission level control of a transmitter of a wireless device according to claim 6, wherein the control is performed so that the detected RF signal approaches the level of the baseband signal. Method. If the control unit determines that the level of the baseband signal is outside the preset control level reference value at the time of the initial operation, the control unit sets an attenuation level with the variable attenuator to 0 dB, and After the power is turned on, the initial operation is set, a pseudo-baseband signal whose level is set in advance from the baseband unit is read, the detected RF signal is read from the RF unit, and then the pseudo baseband signal is read. Is compared with the level of the detection RF signal, and if the level of the detection RF signal is higher than the level of the pseudo baseband signal, the attenuation level of the variable attenuator is lowered. After setting the attenuation level of the variable attenuator by performing a preset number of times of decreasing or increasing the attenuation level, Transmission level control method of a transmitter of a wireless device according to claim 5, characterized in that the initial operation control when the power of the amplifier after to OFF.

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