JP2004040553A - Communication equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent the output level of a transmission wave from being fluctuated even if antennas are switched by antenna diversity control in a receiving mode in communication equipment that can perform transmission and reception at the same time. <P>SOLUTION: A transmitting part 131 is provided with a transmission wave adjusting part 131a, and a digital processing part 14 is provided with a control signal adjusting part 14a. Even though a transmission wave C deteriorates because passing loss occurs in a transmission band pass filter 121 when receiving antennas are switched on the basis of the antenna diversity control, the control signal adjusting part 14a deforms the waveform of a transmission output control signal B and the transmission wave adjusting part 131a adds the deteriorated portion to the transmission wave C in advance on the basis of the deformed transmission output control signal B so as to fill up the deteriorated portion of the transmission wave C that is formed at the time of switching the antennas on the basis of the deformed transmission output control signal B. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a communication device.
[0002]
[Prior art]
2. Description of the Related Art In recent years, communication devices such as mobile phones that can transmit and receive data based on a plurality of communication methods have been realized. In particular, recently, a communication device capable of supporting two communication systems, a TDMA (Time Division Multiple Access) single mode used for low-speed data transmission and an FDP (full duplex; full-duplex transmission) system used for high-speed data transmission, has been developed. It is being developed. In this FDP system, transmission and reception of signals can be performed at high speed and simultaneously.
[0003]
Further, in the above communication device, antenna diversity control corresponding to each communication system of the TDMA system and the FDP system is performed in order to obtain a good reception signal.
[0004]
[Problems to be solved by the invention]
However, the conventional communication device has the following problems.
In the above conventional communication apparatus, when an antenna is switched by antenna diversity control when transmitting based on the FDP method at the time of reception, the output level of the transmission wave fluctuates (hereinafter, the fluctuation of the output level is referred to as deterioration). Modulation accuracy may be degraded.
[0005]
Hereinafter, a block diagram of the communication device 300 as the conventional communication device shown in FIG. 7 and the waveforms of various signal waves in the communication device 300 when the antenna diversity control is performed shown in FIG. The above problem will be specifically described with reference to a waveform diagram showing a change in level). FIG. 8 shows a state in which a transmission wave deteriorates when an antenna is switched by antenna diversity control in communication device 300.
Note that the other configuration of the communication device 300 except for the transmission unit 331 and the digital processing unit 34 has the same configuration as the communication device 100 of the present embodiment described in detail later, Is omitted (see FIG. 1).
[0006]
First, a description will be given of the waveform of a transmission wave when antenna diversity control is performed during transmission of data A31 (section indicated by reference numeral L31 in the figure) in transmission data A. In this case, the communication device 300 transmits based on the PDF method (that is, transmits simultaneously with reception). When the antenna diversity control is performed during the transmission of the data A31 (reference numeral L31 in the figure), the switch 112a operates due to the change of the switch control signal E indicated by the reference numeral W31a in the figure, and the receiving antenna is switched from the antenna 111 to the antenna 112. Once switched. Thereafter, when the reception level signal D decreases as indicated by reference numeral W32 in the figure, the switch control signal E returns to the original state, and the switch 112a operates again to return to the original antenna 111 as indicated by reference numeral W31b in the figure. . Since the impedance between the transmission band-pass filter 121 and the antenna 111 changes while the antenna is switched, the transmission band-pass filter 121 causes the transmission loss of the transmission wave (the location of the transmission wave F indicated by the symbol W33 in the drawing). Occurs.
[0007]
Further, a description will be given of a waveform of a transmission wave when antenna diversity control is performed during transmission of data A32 of transmission data A (section indicated by reference numeral L32 in the drawing). Also in this case, the communication device 300 transmits based on the PDF system (that is, transmits simultaneously with reception). When the antenna diversity control is performed during the transmission of the data A32 (L32 in the figure), the switch 112a operates due to the change of the switch control signal E shown in the figure W34, and the receiving antenna is switched from the antenna 111 to the antenna 112. Can be switched. Thereafter, the reception level signal D is improved as indicated by reference numeral W35 in the figure, so that the antenna 112 is kept switched to the switched antenna 112 for a predetermined time based on the antenna diversity control. After the antenna switching, a change occurs in the impedance between the transmission band-pass filter 121 and the antenna 111, so that a transmission-wave passing loss (a portion of the transmission wave F indicated by the symbol W36 in the drawing) occurs in the transmission band-pass filter 121. .
[0008]
SUMMARY OF THE INVENTION It is an object of the present invention to provide a communication apparatus capable of transmitting and receiving simultaneously so that the output level of a transmission wave does not fluctuate even when an antenna is switched by antenna diversity control during reception.
[0009]
[Means for Solving the Problems]
In order to solve the above problems, the present invention provides:
In a communication device that includes a plurality of communication antennas and can switch antennas according to reception sensitivity at the time of reception and can simultaneously transmit transmission waves,
An adjustment data generation unit that generates adjustment data for adjusting the output level of the transmission wave,
A level adjustment unit that adjusts the output level of the transmission wave based on the adjustment data generated by the adjustment data generation unit,
The adjustment data generator,
The method is characterized in that adjustment data is generated such that the change in the output level of the transmission wave adjusted by the level adjustment unit compensates for the change in the output level of the transmission wave caused by the switching of the antenna.
[0010]
Further, a signal generation unit that generates a data range designation signal for designating a data range to be modulated into a transmission wave among the input data,
The adjustment data generator,
The output data of the data range designation signal is changed by a predetermined amount to be the adjustment data,
The level adjuster includes:
It is preferable that the output level of the transmission wave is adjusted according to the predetermined change in the output level of the data range designation signal generated as the adjustment data by the adjustment data generation unit.
[0011]
Further, the level adjusting unit amplifies the output level of the transmission wave according to the change in the output level of the data range designation signal, or the level of the transmission wave according to the change in the output level of the data range designation signal. Preferably, it is constituted by an attenuator for attenuating the output level.
[0012]
Further, in order to solve the above problems, the present invention provides:
In a communication device that includes a plurality of communication antennas and can switch antennas according to reception sensitivity at the time of reception and can simultaneously transmit transmission waves,
A level adjustment unit that adjusts the output level of the input transmission data,
The level adjuster includes:
The output level of the transmission data is adjusted so that the output level of the transmission wave compensates for a change in the output level of the transmission wave caused by the switching of the antenna.
[0013]
Further, in order to solve the above problems, the present invention provides:
In a communication device that includes a plurality of communication antennas and can switch antennas according to reception sensitivity at the time of reception and can simultaneously transmit transmission waves,
An adjustment data generation unit that generates adjustment data for adjusting the output level of the transmission wave,
A first level adjustment unit that adjusts an output level of the transmission wave based on adjustment data generated by the adjustment data generation unit;
A second level adjustment unit that adjusts the output level of the input transmission data,
The adjustment data generator,
The output level of the transmission wave adjusted by the first level adjustment unit generates adjustment data for compensating for a change in the output level of the transmission wave caused by switching of the antenna,
The second level adjuster includes:
The output level of the transmission data is adjusted so that the output level of the transmission wave compensates for a change in the output level of the transmission wave caused by the switching of the antenna.
[0014]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the communication device 100 according to the embodiment of the present invention will be described in detail with reference to the drawings.
[0015]
First, the configuration of the communication device 100 will be described with reference to FIG.
FIG. 1 is a block diagram showing a main configuration of communication device 100. The communication device 100 is a communication device that can support two communication systems, a TDMA single mode used for low-speed data transmission and an FDP system used for high-speed data transmission. In this FDP system, signal transmission and reception can be performed at high speed and simultaneously. In addition, the communication device 100 performs antenna diversity control corresponding to each communication system of the TDMA system and the FDP system in order to obtain a good reception signal. This antenna diversity control is also performed when a transmission wave is transmitted based on the FDP scheme during reception.
[0016]
As shown in FIG. 1, the communication device 100 includes antennas 111 and 112, a switch 112a, a duplexer 12, a transmission unit 131, a reception unit 132, a digital processing unit 14, an audio unit 15, a microphone 15a, a speaker 15b, a display unit 16, and the like. It comprises. Further, the duplexer 12 includes a transmission band-pass filter 121 and a reception band-pass filter 122, and the transmission unit 131 includes a transmission wave adjustment unit 131a. Here, the digital processing unit 14 realizes the function of the signal generation unit described in the claims of the present invention, the control signal adjustment unit 14a realizes the function of the adjustment data generation unit, and the transmission wave correction unit 131a or 131b implements the function of the (first) level adjustment unit.
[0017]
The antenna 111 is connected to the transmission band-pass filter 121, but can also be connected to the reception band-pass filter 122 via the switch 112a. The antenna 112 is connectable to the reception bandpass filter 122 via the switch 112a. That is, the antenna 111 is a transmission / reception antenna, and the antenna 112 is a reception-only antenna. The switch 112a performs a switching operation based on the switch control signal E input from the digital processing unit 14 to connect a receiving antenna (ie, an antenna connected to the reception bandpass filter 122) between the antenna 111 and the antenna 112. To switch.
[0018]
The transmission band-pass filter 121 included in the duplexer 12 is configured by a dielectric filter, a SAW filter, or the like, and includes a frequency band included in the transmission wave C input from the transmission unit 131 (that is, a communication system (for example, Only a signal wave in a transmission wave frequency band (PDC (Personal Digital Cellular) system) is passed, and signal waves in other frequency bands are blocked and suppressed. Further, the reception band-pass filter 122 is configured by a surface acoustic wave filter or the like, and receives a reception wave of a frequency band (that is, a communication system (for example, a PDC system) that can be supported by the communication device 100) of the reception wave input to the reception unit 132. Frequency band), and blocks and suppresses signal waves in other frequency bands.
[0019]
The transmission unit 131 performs transmission processing such as modulation and amplification on the transmission data A input from the digital processing unit 14 to generate a transmission wave C, and inputs the transmission wave C to the transmission bandpass filter 121 of the duplexer 12. I do. In this case, based on the transmission output control signal B input from the digital processing unit 14, the transmission unit 131 outputs data to be output as a transmission wave from the transmission data A input from the digital processing unit 14 (for example, FIG. (Data A11, A12, etc. of the transmission data A shown in FIG. 1), and a transmission wave for the extracted data is generated.
[0020]
The transmission unit 131 includes a transmission wave adjustment unit 131a including the voltage variable gain amplifier illustrated in FIG. 3A, and adjusts the output level of the transmission wave C based on the transmission output control signal B (hereinafter, adjustment of the output level). To transform the waveform). As shown in FIG. 3A, the transmission wave adjustment unit 131a has a circuit including a transistor Tr11, resistors R11 to R13, capacitors C11 to C15, induction coils I11 and I12, and a transmission output control signal B The transmission wave input on the IN side is amplified according to the value of (voltage V1) (that is, the waveform of the transmission wave is modified) and output to the OUT side. Here, FIG. 3B shows the correlation between the voltage V1 and the gain of the transmission wave adjustment unit 131a. As shown in FIG. 3B, the gain of the transmission wave adjustment unit 131a responds substantially linearly to the increase and decrease of the voltage V1. That is, the transmission wave adjustment unit 131a transforms the transmission wave input from the IN side into a transmission wave C having a waveform substantially similar to the transmission output control signal B (voltage V1) input from the digital processing unit 14, and converts the transmission wave into a transmission wave C on the OUT side. Output from
[0021]
Accordingly, the transmission wave adjustment unit 131a compensates for the deterioration of the transmission wave C generated when the antenna is switched by the antenna diversity control according to the transmission output control signal B (voltage V1) input from the digital processing unit 14. The transmission wave C is transformed into such a waveform. In this case, the transmission output control signal B has a waveform substantially similar to the waveform of the transmission wave C that can compensate for the degradation.
Thereby, even if the antenna is switched by the antenna diversity control, the deterioration of the transmission wave C can be avoided (see FIG. 2 for the waveform of the transmission wave C).
[0022]
Note that the transmission unit 131 may have a configuration including a transmission wave correction unit 131b including a voltage variable attenuator shown in FIG. 4A instead of the transmission wave adjustment unit 131a. As shown in FIG. 4A, the transmission wave correction unit 131b includes a circuit including an induction coil I21, a diode D21, capacitors C21 to C23, resistors R21 and R22, and a transmission output control signal B (voltage The waveform of the transmission wave input on the IN side is transformed according to the value of V2) and output to the OUT side.
[0023]
The reception unit 132 extracts an IF signal from the reception wave input from the reception bandpass filter 122 of the duplexer 12 and inputs the IF signal to the digital processing unit 14. Further, receiving section 132 detects the reception level of the reception wave input from reception band-pass filter 122 (that is, the electrolytic strength of the reception wave), and receives an RSSI (Received Signal Strength Indication) signal (hereinafter, reception level signal) indicating the reception level. D) is generated and input to the digital processing unit 14.
[0024]
The digital processing unit 14 converts an analog transmission voice signal input from the audio unit 15 into digital data by D / A (Digital / Analog) conversion, and performs code conversion or the like on digital data such as document data. Perform error correction, etc. Further, the digital processing unit 14 performs processing based on the TDMA single mode method or the FDP method on the digital data such as the transmission voice and the document data to generate transmission data A, and transmits the transmission data A to the transmission unit 131. input.
[0025]
The digital processing unit 14 inputs the transmission output control signal B to the transmission unit 131 and instructs the transmission unit 131 to generate a transmission wave C for the transmission data A.
[0026]
The digital processing unit 14 includes a control signal adjustment unit 14a. When the antenna diversity control is performed during the transmission processing based on the FDP scheme, the control signal adjustment unit 14a deforms the waveform of the transmission output control signal B for the following use. That is, the control signal adjustment unit 14a deforms the waveform of the transmission wave C so that the transmission wave adjustment unit 131a can compensate for the deterioration of the transmission wave C generated at the time of antenna switching based on the modified transmission output control signal B. The waveform of the transmission output control signal B is modified (see FIG. 2 for the waveform of the transmission output control signal B). In this case, it is assumed that the deformation data for deforming the waveform of the transmission output control signal B is stored in a memory (not shown) of the digital processing unit 14 in advance. The digital processing unit 14 deforms the waveform of the transmission output control signal B based on the deformed data.
[0027]
The digital processing unit 14 converts the IF signal input from the receiving unit 132 into digital data by D / A (Digital / Analog) conversion, performs processing based on the TDMA single mode method or the FDP method, and performs a process based on the received voice signal or the like. Extract text messages, etc. Further, the digital processing unit 14 inputs the received voice signal to the audio unit 15 and performs code conversion, error correction, and the like on digital data such as document data.
[0028]
The digital processing unit 14 performs antenna diversity control based on the reception level signal D input from the reception unit 132. That is, the digital processing unit 14 transmits the switch control signal E to the switch 112a based on the reception level signal D to obtain a good reception wave (that is, so that the reception level signal D becomes large), and Is switched between the antenna 111 and the antenna 112.
[0029]
Next, the operation of the communication device 100 will be described with reference to FIG.
FIG. 2 is a waveform diagram showing waveforms of various signal waves when antenna diversity control is performed in communication device 100.
[0030]
First, a description will be given of a waveform of a transmission wave when antenna diversity control is performed during transmission of data A11 of transmission data A (section indicated by reference numeral L11 in the drawing). In this case, the communication device 100 performs transmission based on the PDF system (that is, transmits simultaneously with reception).
[0031]
When performing the antenna diversity control during the transmission of the data A11, the digital processing unit 14 changes the switch control signal E as indicated by the reference sign W11a in the figure to operate the switch 112a. The switch 112a switches the receiving antenna from, for example, the antenna 111 to the antenna 112 according to the switch control signal E.
[0032]
Thereafter, when the reception level signal D decreases as shown by the reference numeral W12 in the figure, the digital processing unit 14 changes the switch control signal E as shown by the reference numeral W11b in the figure to operate the switch 112a, and the antenna is turned off. To the antenna 111.
[0033]
The switching of the receiving antenna from the antenna 111 to the antenna 112 causes a change in the impedance between the transmission band-pass filter 121 and the antenna 111, so that the transmission band-pass filter 121 causes a transmission loss of the transmission wave. In this case, the control signal adjusting unit 14a included in the digital processing unit 14 projects the waveform of the transmission output control signal B to the reference symbols W13a and W13b at substantially the same timing as the switch control signal E at the timings W11a and W11b. The transmission wave adjusting unit 131a deforms the waveform of the transmission wave C based on the transmission output control signal B deformed by the convex shape so as to compensate for the deterioration of the transmission wave C generated when the antenna is switched. It is deformed by the amount of the convex shape shown by reference numerals W14a and W14b in the figure.
[0034]
Since the transmission wave C has been deformed by the convex shape indicated by reference numerals W14a and W14b in the figure, the convex shape compensates for the transmission loss of the transmission wave C generated at the time of antenna switching, and as a result, the transmission wave without deterioration F is obtained.
[0035]
Next, a description will be given of a waveform of a transmission wave when antenna diversity control is performed during transmission of data A12 of transmission data A (section indicated by reference numeral L12 in the drawing). Also in this case, the communication device 100 performs transmission based on the PDF system.
[0036]
When performing the antenna diversity control during the transmission of the data A12, the digital processing unit 14 changes the switch control signal E as indicated by the reference numeral W15 in the figure to operate the switch 112a. The switch 112a switches the receiving antenna from the antenna 111 to the antenna 112 according to the switch control signal E.
[0037]
Thereafter, the reception level signal D is improved as indicated by a symbol W16 in the figure, so that the digital processing unit 14 keeps switching to the switched antenna 112 for a predetermined time based on the antenna diversity control.
[0038]
The switching of the receiving antenna from the antenna 111 to the antenna 112 causes a change in the impedance between the transmission band-pass filter 121 and the antenna 111, so that the transmission band-pass filter 121 causes a transmission loss of the transmission wave. In this case, the control signal adjusting unit 14a included in the digital processing unit 14 deforms the switch control signal E by increasing the waveform of the transmission output control signal B at substantially the same timing as the symbol W15 in the figure by the amount indicated by the symbol W17 in the figure. Then, based on the transmission output control signal B after the deformation, the transmission wave adjusting unit 131a changes the waveform of the transmission wave C by the amount indicated by the reference symbol W18 in the drawing so as to compensate for the deterioration of the transmission wave C generated when the antenna is switched. Deform.
[0039]
Since the transmission wave C has been deformed as indicated by reference numeral W18 in the figure, the transmission loss of the transmission wave C generated at the time of antenna switching is compensated for by the deformation, and as a result, the transmission wave F without deterioration is obtained.
[0040]
As described above, the communication device 100 of the present embodiment includes the transmission wave adjustment unit 131a in the transmission unit 131 and the control signal adjustment unit 14a in the digital processing unit 14. When the receiving antenna is switched based on the antenna diversity control, a transmission loss occurs in the transmission band-pass filter 121 and the transmission wave C is deteriorated. However, the control signal adjusting unit 14a deforms the waveform of the transmission output control signal B, The transmission wave adjusting unit 131a is configured to correct the deterioration of the transmission output control signal B based on the deformed transmission output control signal B so as to compensate for the deterioration of the transmission wave C generated when the antenna is switched based on the modified transmission output control signal B. Is added to the transmission wave C in advance.
[0041]
Therefore, even if the receiving antenna is switched by the antenna diversity control, it is possible to avoid the deterioration of the transmission wave.
[0042]
The description in the present embodiment shows an example of the communication device according to the present invention, and the present invention is not limited to this. The detailed configuration and detailed operation of the communication device 100 according to the present embodiment can be appropriately changed without departing from the spirit of the present invention.
[0043]
For example, the transmission data A itself may be modified in advance instead of modifying the transmission output control signal B in order to compensate for the deterioration of the transmission wave C caused when the antenna is switched. Further, a configuration in which an external antenna other than the antenna 111 and the antenna 112 is detachably provided may be employed. FIG. 5 shows a communication device 200 having such a function. FIG. 5 is a block diagram showing a main configuration of the communication device 200.
[0044]
Note that the other configuration of the communication device 200 except for the transmission unit 231, the digital processing unit 24, the switch 111a, and the switch 112b illustrated in FIG. 5 has the same configuration as the communication device 100 according to the present embodiment. The description is omitted by attaching reference numerals (see FIG. 1). Here, the transmission data adjustment unit 24a realizes the function of the (second) level adjustment unit described in the claims of the present invention.
[0045]
The switch 111a is a switch for switching between the antenna 111 and the external antenna terminal G1 by the antenna diversity control by the digital processing unit 24. The switch 112b is a switch for switching between the antenna 111, the external antenna terminal G1, the antenna 112, and the external antenna terminal G2 by the antenna diversity control by the digital processing unit 24.
If the external antenna can be connected in this manner, the choice of antennas that can be switched by the antenna diversity control is expanded, so that the reception sensitivity is improved.
[0046]
The digital processing unit 24 includes a transmission data adjustment unit 24a for transforming the transmission data A. When the antenna diversity control is performed during the transmission processing based on the FDP scheme, the transmission data adjustment unit 24a deforms the transmission data A so as to compensate for the deterioration of the transmission wave C that occurs when the antenna is switched. (Refer to FIG. 6 for the waveform of the transmission data A, which will be described in detail later.)
[0047]
Here, the operation of the communication device 200 will be described with reference to FIG. FIG. 6 is a waveform diagram showing waveforms of various signals when antenna diversity control is performed in communication device 200.
[0048]
First, a description will be given of a waveform of a transmission wave when antenna diversity control is performed during transmission of data A21 of transmission data A (section indicated by reference numeral L21 in the drawing). In this case, the communication device 200 performs transmission based on the PDF system.
[0049]
When performing the antenna diversity control during the transmission of the data A21, the digital processing unit 24 changes the switch control signal E as indicated by the reference numeral W21a in the figure to operate the switches 111a and 112b. The switches 111a and 112b switch the receiving antenna according to the switch control signal E.
[0050]
When the reception level signal D decreases as indicated by reference numeral W22 in the drawing due to the antenna switching, the digital processing unit 24 changes the switch control signal E as indicated by reference numeral W21b to operate the switches 111a and 112b. , Return the antenna to the original antenna.
[0051]
When the receiving antenna is switched as described above, a change occurs in the impedance between the transmission band-pass filter 121 and the transmitting antenna (the antenna 111 or an external antenna (not shown) connected to the external antenna terminal G1), For this reason, a transmission wave passing loss occurs in the transmission band-pass filter 121. In this case, the transmission data adjustment unit 24a included in the digital processing unit 24 converts the waveform of the transmission data A of the switch control signal E at substantially the same timing as that of the symbols W21a and W21b in FIG. Only to make it possible to compensate for the deterioration of the transmission wave C that occurs when the antenna is switched.
[0052]
The transmission wave C output from the transmission unit 231 is deformed by the convex shape indicated by the reference symbols W24a and W24b in the figure. As a result, a transmission wave F without deterioration is obtained.
[0053]
Next, a description will be given of a waveform of a transmission wave when antenna diversity control is performed during transmission of data A22 of transmission data A (section indicated by reference numeral L22 in the drawing). Also in this case, the communication device 200 performs transmission based on the PDF system.
[0054]
When performing the antenna diversity control during the transmission of the data A22, the digital processing unit 24 changes the switch control signal E as indicated by the reference numeral W25 in the figure to operate the switches 111a and 112b. The switches 111a and 112b switch the receiving antenna according to the switch control signal E.
[0055]
As a result of the antenna switching, the reception level signal D is improved as indicated by reference numeral W26 in the figure, so that the digital processing unit 24 keeps switching to the switched antenna for a predetermined time based on the antenna diversity control.
[0056]
When the receiving antenna is switched as described above, a change occurs in the impedance between the transmission band-pass filter 121 and the transmitting antenna (the antenna 111 or an external antenna (not shown) connected to the external antenna terminal G1), For this reason, a transmission wave passing loss occurs in the transmission band-pass filter 121. In this case, the transmission data adjustment unit 24a included in the digital processing unit 24 deforms the switch control signal E by increasing the waveform of the transmission data A by the amount indicated by the reference character W27 at substantially the same timing as the reference character W25 in the drawing, It is possible to compensate for the deterioration of the transmission wave C that occurs when the antenna is switched.
[0057]
The transmission wave C output from the transmission unit 231 is deformed by the amount indicated by the reference character W28 in the figure, so that the transmission loss of the transmission wave C generated at the time of antenna switching is compensated for by the deformation, and as a result, transmission without deterioration is performed. A wave F is obtained.
[0058]
Therefore, according to the communication device 200, the transmission data A itself is deformed in advance by the transmission data adjustment unit 24a of the digital processing unit 24, instead of the transmission wave C being deformed by the transmission wave adjustment unit 131a of the transmission unit 131. Therefore, except for the modification of the transmission data A by the transmission data adjustment unit 24a, the deterioration of the transmission wave C can be compensated by the same processing as that of the conventional communication device 300 shown in FIG. 7, and the configuration of the communication device 200 is simplified. It becomes a thing.
[0059]
The technical idea of the present invention is also applicable to a communication device (not shown) having a configuration having the functions of the communication devices 100 and 200 described above. That is, such a communication device includes the digital signal processing unit 14 with the control signal adjustment unit 14a and the transmission data adjustment unit 24a, and the transmission unit 131 with the transmission wave correction unit 131a or 131b. A function of adjusting the output level of B to deform the waveform of the transmission wave C (hereinafter referred to as function 1) and a function of adjusting the output level of the transmission data A itself to deform the waveform of the transmission wave C (hereinafter, function) 2). In this case, for example, even if the waveform of the transmission wave C is deformed by one of the functions 1, even if the function 1 alone cannot completely compensate for the deterioration of the transmission wave C, the other function 2 is not used. It can be used to supplement. That is, the simultaneous use of both functions 1 and 2 makes it possible to more completely compensate for the deterioration of the transmission wave C.
[0060]
【The invention's effect】
ADVANTAGE OF THE INVENTION According to this invention, in the communication apparatus which can perform transmission and reception simultaneously, even if an antenna switches by antenna diversity control at the time of a reception, it can be made that the output level of a transmission wave does not fluctuate.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a main configuration of a communication device according to an embodiment of the present invention.
FIG. 2 is a waveform diagram showing waveforms of various signal waves when antenna diversity control is performed in the communication device according to the embodiment of the present invention.
3A is a block diagram illustrating a configuration of a voltage variable gain amplifier as an example of a transmission wave correction unit illustrated in FIG. 1, and FIG. 3B is a graph illustrating characteristics of the voltage variable gain amplifier; is there.
4A is a block diagram illustrating a configuration of a variable voltage attenuator as another example of the transmission wave correction unit illustrated in FIG. 1, and FIG. 4B illustrates characteristics of the variable voltage attenuator; It is a graph.
FIG. 5 is a block diagram showing a main configuration of a communication device according to another embodiment to which the present invention is applied.
FIG. 6 is a waveform diagram showing waveforms of various signal waves when antenna diversity control is performed in a communication device according to another embodiment of the present invention.
FIG. 7 is a block diagram illustrating a main configuration of a conventional communication device.
8 is a waveform diagram showing waveforms of various signal waves when antenna diversity control is performed in the communication device shown in FIG.
[Explanation of symbols]
100 Communication device
111, 112 antenna
112a switch
12 Duplexer
121 transmission bandpass filter
122 Receive bandpass filter
131 transmission unit
131a transmission wave adjustment unit
132 Receiver
14 Digital processing section
14a control signal adjustment unit
15 Audio section
15a microphone
15b speaker
16 Display
200 communication device
111a switch
112b switch
231 Transmission unit
24 Digital processing unit
24a Transmission data adjustment unit
G1, G2 external antenna terminals

Claims (5)

In a communication device that includes a plurality of communication antennas and can switch antennas according to reception sensitivity at the time of reception and can simultaneously transmit transmission waves,
An adjustment data generation unit that generates adjustment data for adjusting the output level of the transmission wave,
A level adjustment unit that adjusts the output level of the transmission wave based on the adjustment data generated by the adjustment data generation unit,
The adjustment data generator,
The communication apparatus according to claim 1, wherein a change in the output level of the transmission wave adjusted by the level adjustment unit compensates for a change in the output level of the transmission wave caused by the switching of the antenna. A signal generation unit that generates a data range designation signal for designating a data range to be modulated to a transmission wave among input data,
The adjustment data generator,
The output data of the data range designation signal is changed by a predetermined amount to be the adjustment data,
The level adjuster includes:
The communication according to claim 1, wherein an output level of a transmission wave is adjusted in accordance with the predetermined change in an output level of the data range designation signal generated as the adjustment data by the adjustment data generation unit. apparatus. The level adjuster is an amplifier that amplifies the output level of the transmission wave according to the change in the output level of the data range designation signal, or the output level of the transmission wave according to the change in the output level of the data range designation signal. The communication device according to claim 1, wherein the communication device is configured by an attenuator that attenuates the signal. In a communication device that includes a plurality of communication antennas and can switch antennas according to reception sensitivity at the time of reception and can simultaneously transmit transmission waves,
A level adjustment unit that adjusts the output level of the input transmission data,
The level adjuster includes:
A communication device, wherein the output level of the transmission data is adjusted so that the output level of the transmission wave compensates for a change in the output level of the transmission wave caused by switching of the antenna. In a communication device that includes a plurality of communication antennas and can switch antennas according to reception sensitivity at the time of reception and can simultaneously transmit transmission waves,
An adjustment data generation unit that generates adjustment data for adjusting the output level of the transmission wave,
A first level adjustment unit that adjusts an output level of the transmission wave based on adjustment data generated by the adjustment data generation unit;
A second level adjustment unit that adjusts the output level of the input transmission data,
The adjustment data generator,
The output level of the transmission wave adjusted by the first level adjustment unit generates adjustment data for compensating for a change in the output level of the transmission wave caused by switching of the antenna,
The second level adjuster includes:
A communication device, wherein the output level of the transmission data is adjusted so that the output level of the transmission wave compensates for a change in the output level of the transmission wave caused by switching of the antenna.

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