JPH08237185A - Terminal equipment for mobile communication - Google Patents

Abstract

PURPOSE: To improve the operability by keeping an output sound volume to be a preceding volume automatically even when a sensitivity frequency characteristic for a voice frequency band is selected so as to facilitate the identification of a speech content corresponding to an operating environment or the like. CONSTITUTION: A switching control signal used to select a frequency characteristic of a digital filter 17 is fed to a filter coefficient memory 18 and a gain information memory 20. An input signal passes through the filter 17 with a frequency characteristic corresponding to a filter coefficient read from the coefficient memory 18 and is given to a variable gain amplifier 19 via a D/A converter 12. A change in output power with respect to input power corresponding to the frequency characteristic of the filter 17 is obtained in advance corresponding to the frequency characteristic to obtain gain information to make an output sound volume constant and it is stored in a gain information memory 20. The gain information read from the memory 20 is fed to the variable gain amplifier 19, which is controlled such that an output sound volume change due to selection of the frequency characteristic is not caused.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mobile communication terminal such as a mobile phone capable of adjusting sound quality in accordance with usage conditions. Unlike a wired telephone, a mobile communication terminal such as a mobile telephone has a significantly different usage environment. In addition, since it is often used outdoors, the call condition is significantly deteriorated as compared with the case of using a general wire telephone. Therefore,
It is conceivable to switch the frequency characteristics so that the content of the call can be easily identified in accordance with the usage environment. There is a demand for easy switching operation in that case.

[0002]

2. Description of the Related Art Wired telephones are mostly used indoors, and their sensitivity frequency characteristics in the voice band are constructed so as to satisfy a mask (standard) according to industrial standards. Also, mobile communication terminals such as mobile phones have the same sensitivity frequency in the voice band as that of wired phones.

However, the mobile communication terminal has a great difference in usage environment and usage conditions. For example, it is used in a noisy environment or outdoors in a strong wind and rain environment. There are cases, etc. Therefore, if all the sensitivity frequency characteristics in the voice band are the same, it may be easy to hear under certain conditions, but it may be difficult to hear under other conditions.

Therefore, a mobile communication terminal for switching the sensitivity frequency characteristic of the voice band in accordance with the use environment and the use condition was previously proposed (see Japanese Patent Application No. 6-86140). This mobile communication terminal switches the frequency characteristic of a received voice signal by an analog circuit or a digital circuit. For example, the frequency characteristic is switched by switching the circuit constant of an analog filter. Alternatively, a configuration is shown in which the frequency characteristics are switched by combining a plurality of analog filters each having a different center frequency and a level adjuster to switch and adjust the level for each divided band. Also, the frequency characteristic can be switched by switching the filter coefficient of the digital filter.

[0005]

In a mobile communication terminal in which the use environment and use conditions are not constant, even if the sensitivity frequency characteristic of the voice band satisfies the standard, the received voice is difficult to hear. There is. Therefore, as described above, the configuration in which the sensitivity frequency characteristic of the voice band is switched according to the usage environment and usage conditions has been previously proposed. With such a configuration, the frequency characteristic can be switched so that it can be heard easily even when it is used by an elderly person or the like whose hearing ability has deteriorated. However, since the output sound volume changes by switching the frequency characteristics of the filter, it is necessary to adjust the sound volume after switching the frequency characteristics. Therefore, the operability was not sufficient.
It is an object of the present invention to automatically maintain the previous state of output volume even if the sensitivity frequency characteristic of the voice band is switched.

[0006]

A mobile communication terminal according to the present invention will be described with reference to FIG. 1. (1) At least a radio receiving section 1, a signal processing section 2 and a desired voice signal are received. In the mobile communication terminal having the acoustic control filter 3 that gives the frequency characteristic of 1. and the handset 4, the acoustic control filter 3 includes the filter unit 5 that switches the frequency characteristic by the switching control signal, and the frequency of the filter unit 5. An output control unit 6 that switches and amplifies the gain so that the output volume does not change in response to the characteristic switching is provided. Further, 7 is a transmitter / receiver such as a circulator, 8 is an antenna, 9 is a wireless transmitter, and 1
Reference numeral 0 represents a signal processing unit, and 11 represents a transmitter.

(2) Further, the acoustic control filter 3 outputs a digital filter, a filter coefficient memory for reading the filter coefficient for switching the frequency characteristic of the digital filter by the switching control signal and adding it to the digital filter, and an output signal of the digital filter. A variable gain amplifier for amplifying and a gain information memory for reading gain information for controlling the gain of the variable gain amplifier so as not to change the output volume by the switching control signal and adding the gain information to the variable gain amplifier are provided.

(3) Further, the acoustic control filter 3 includes a filter section 5 and an output control section 6, and the filter section 5 reads out a filter coefficient from a filter coefficient memory according to a switching control signal. The output control unit 6 includes a gain information memory for reading the gain information by the switching control signal, and an output volume change by frequency switching by the gain information read from the gain information memory. And a variable gain amplifier that amplifies the output signal of the filter unit 5 by controlling the gain so as not to occur.

(4) Further, the acoustic control filter 3 includes a filter section 5 for switching frequency characteristics by a switching control signal, an output control section 6 for amplifying and outputting an output signal of the filter section 5, and an output power control section. And the output power controller is
Based on the average value of the input power and the average value of the output power of the filter unit 5, the output control unit 6 is controlled so that the output volume change due to the frequency characteristic switching does not occur.

(5) Further, the acoustic control filter 3 has a buffer memory for accumulating an input signal of at least one frame length, a digital filter for adding the input signal via the buffer memory, and a frequency of the digital filter according to the switching control signal. A filter coefficient memory for reading the filter coefficient for switching the characteristics, a variable gain amplifier for amplifying the output signal of the digital filter, and a variable gain amplifier based on the average value of the input power and the average value of the output power of the digital filter. An output power control circuit for controlling the gain is provided, and the output power control circuit has an average value of the input power and an average value of the output power for each frame period shorter than the frame length for a predetermined frame length of the input signal of the digital filter. To the output signal of this power calculation circuit And a gain calculation circuit for calculating the gain of the variable gain amplifier to.

[0011]

[Action]

(1) A reception signal is applied from the antenna 8 to the wireless reception unit 1 through the duplexer 7, the demodulation and the like are performed in the wireless reception unit 1, and the audio signal is decoded and the like by the signal processing unit 2. The audio signal given the desired frequency characteristic by the acoustic control filter 3 is applied to the handset 4. The acoustic control filter 3 includes a filter unit 5 and an output control unit 6, and switches the frequency characteristic of the voice from the handset 4 by a switching control signal to make selection so that it becomes easy to hear. The average input power of the handset 4 changes due to the switching of the frequency characteristics,
Since the output volume of the handset 4 changes, the output control unit 6 is controlled in response to the switching of the frequency characteristic so that the output volume does not change due to the switching of the frequency characteristic. Therefore, the output volume of the handset 4 does not change, and the operability is improved.

(2) Further, the filter section 5 of the acoustic control filter 3 is composed of a digital filter and a filter coefficient memory, and the output control section 6 is composed of a variable gain amplifier and a gain information memory. The filter coefficient is read from the filter coefficient memory by the switching control signal and added to the digital filter to switch the frequency characteristic.The switching control signal reads the gain information from the gain information memory and added to the variable gain amplifier, and the output volume is switched by the frequency characteristic switching. The gain of the variable gain amplifier is controlled so that no change occurs. Therefore, it is possible to switch to a frequency characteristic that is easy to hear, and it is not necessary to readjust the output volume.

(3) Further, the filter unit 5 of the acoustic control filter 3 is used as an analog filter, and the filter constant is switched by the switching control signal to switch the frequency characteristic. The output control unit 6 is composed of a variable gain amplifier and a gain information memory, and controls the gain of the variable gain amplifier so that the output volume does not change due to the frequency characteristic switching.

(4) Further, the filter unit 5 has a structure for switching the frequency characteristic according to the switching control signal, the output control unit 6 has a variable gain amplifier, and the output power control circuit has an average of the input power of the filter unit 5. The value and the average value of the output power are respectively obtained, and the gain of the variable gain amplifier is controlled in accordance with the ratio or the difference between the average values. For example, when the ratio or the difference of the average values is large, it indicates that the average value of the output power is small. Therefore, the gain of the variable gain amplifier is increased to control so that the output volume does not change.

(5) Further, the acoustic control memory 3 is composed of a buffer memory, an output power control circuit, a filter section 5, and an output control section 6, and the power calculation circuit of the output power control circuit causes the filter section 5 to operate. The average value of the input power and the average value of the output power are calculated for the frame length of the input signal.
If the frame length is, for example, 20 ms, the average value of the input power and the average value of the output power are obtained every 20 ms, for example, in a shorter frame period. Then, the average value ratio or difference is obtained. Further, the gain calculation circuit of the output power control circuit calculates the gain for controlling the variable gain amplifier of the output control unit 6 in accordance with the ratio or difference of the average values. For example,
When the ratio or difference of the average values becomes large due to the switching of the frequency characteristics, it indicates that the average value of the output power has decreased. Therefore, the gain calculation circuit calculates the gain information for increasing the gain of the variable gain amplifier. Therefore, even if the output power of the filter unit 5 is reduced due to the switching of the frequency characteristics, the variable gain amplifier can amplify the output power to the original state, so that the output volume can be made constant.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS As shown in FIG. 1, the essential parts of a mobile communication terminal are a radio receiving section 1, a signal processing section 2, an acoustic control filter 3, a receiver 4, a transmitter 11, and a signal. Processing unit 10
The wireless transmission unit 9, the duplexer 7, and the antenna 8 are included. The signal received by the wireless receiving unit 1 from the antenna 8 via the duplexer 7 is demodulated, the signal processing unit 2 decodes the signal, and the sound control filter 3 gives a desired frequency characteristic to the audio signal. The voice signal is applied to the handset 4. Further, the signal processing unit 10 performs AD conversion and encoding processing on the voice signal from the transmitter 11, modulates it into a radio frequency in the radio transmission unit 9, and transmits it from the antenna 8 via the duplexer 7. To do.

The acoustic control filter 3 includes a filter section 5 and an output control section 6. The filter section 5 is composed of a digital circuit or an analog circuit, and has a frequency characteristic of, for example, 50 Hz to 8 kHz in the voice band according to the switching control signal. It has a configuration in which switching is performed. Further, the output control unit 6 uses, for example, a path of a dotted line, etc.
The gain is controlled in accordance with the switching of the frequency characteristic, and the output volume of the handset 4 is configured not to change even when the frequency characteristic is switched. Since the relationship between the frequency characteristic of the filter unit 5 and the amplification gain of the output control unit 6 can be obtained in advance, the frequency characteristic is switched by the switching control signal and the amplification gain of the output control unit 6 is controlled. Thus, the output volume of the handset 4 can be made constant.

FIG. 2 is an explanatory view of the essential portions of the first embodiment of the present invention. 12 is a DA converter (D / A), 13 is an acoustic control filter, 14 is a receiver, 15 is a filter section, and 16 is a filter. An output control unit, 17 is a digital filter, 18 is a filter coefficient memory, 19 is a variable gain amplifier, and 20 is a gain information memory, and shows a configuration corresponding to the portion of the acoustic control filter 3 in FIG.

A switching control signal for switching the frequency characteristic of the filter section 15 is added to the filter coefficient memory 18 and the gain information memory 20, and the filter coefficient read from the filter coefficient memory 18 is added to the digital filter 17. The digital filter 17 is latched and has a frequency characteristic corresponding to the filter coefficient. Further, the gain information read from the gain information memory 20 is the variable gain amplifier 19
The output volume is controlled by the frequency characteristic switching so as not to change.

The change in the output power with respect to the input power corresponding to the frequency characteristic of the digital filter 17 can be obtained in advance corresponding to the frequency characteristic, and the gain information for making the output volume constant can be obtained based on the change. The gain information can be stored in the gain information memory 17 corresponding to the switching control signal. Therefore, the filter coefficient memory 18 and the gain information memory 20 can be configured by a read only memory (ROM) or a random access memory (RAM). Further, a case where the variable gain amplifier 19 is configured by an analog circuit is shown. The output signal of the digital filter 17 is converted into an analog signal by the DA converter 12 and input to the variable gain amplifier 19, and the amplified output signal is input to the receiver 14. Add.

When the user of the mobile communication terminal operates the changeover of the frequency characteristic with the changeover switch or the numeric keypad, the changeover control signal is added as the address signal of the gain information memory 20 and the filter coefficient memory 18, and the gain is increased. The gain information of the variable gain amplifier 19 is read from the information memory 20, and the digital filter 1 is read from the filter coefficient memory 18.
The filter coefficients of 7 are read. Thereby, the frequency characteristic of the digital filter 17 is switched. In this case, the average value of the output power of the digital filter 17 changes due to the change of the frequency characteristic, but the gain of the variable gain amplifier 19 is changed, and the average value of the output power of the variable gain amplifier 19 becomes The value is controlled to be the same as before switching. Therefore, the output volume of the handset 14 does not change.

FIG. 3 is an explanatory view of an example of a digital filter, 17 and 18 correspond to the digital filter and the filter coefficient memory of Fig. 2, 21 _{0-21 2,} 24
₁ and 24 ₂ are coefficient units, 22 _{0 to} 22 ₂ are adders, 2
Reference numerals 3 ₀ and 23 ₁ are delay elements (Z ^-1 ) for one sample time of the digital input signal.

The input signal is applied to the adder 22 _{0-22 2} via the coefficient multiplier 21 _{0-21 2.} Also adder 22 ₀
The output signal the output signal of the digital filter 17, together with the applied to the variable gain amplifier (not shown) through a subsequent stage of the DA converter, coefficient unit 24 _1, 24 ₂ adders 22 ₁ through 22 ₂ added to the output signal of the adder 22 ₂ is applied to the adder 22 ₁ via the delay element 23 _1, the output signal of the adder 22 ₁ is added to the adder 22 ₀ via the delay element 23 ₀ .

In addition, the filter coefficient memory corresponding to the switching control signal.
Filter coefficient a read from memory 18₀k to a₂k,
-B₁k, -b₂k is a coefficient unit 21₀~ 21₂, 24₁,
24 ₂Added to. These filter coefficients a₀k to a
₂k, -b₁k, -b₂By changing k
The frequency characteristic of the digital filter 17 can be changed.
It The digital filter 17 has a frequency to be switched.
Various configurations can be adopted according to the type of characteristics
It

FIG. 4 is an equal loudness curve diagram, which is 1 kHz.
The sound pressure level is shown for each frequency where z is the reference sound and the same sound pressure as the reference sound is felt.
Indicates a loudness level of 0 to 120. That is, it is known that the lower the loudness level, the lower the hearing in the low range and the high range.

FIG. 5 is a relationship curve diagram between age and hearing,
For example, at a frequency of 1 kHz, when the age is 50, the hearing loss is about 3 dB, and when the age is 70, the hearing loss is about 13 dB at the frequency of 1 kHz. At a frequency of 4 kHz, the hearing acuity is reduced by about 15 dB at the age of 50 and at about 30 dB at the age of 70 at the frequency of 4 kHz. That is, the elderly people have a tendency to deteriorate the high-pitched hearing. Therefore, when an elderly person uses a mobile terminal, it is desirable to switch to a frequency characteristic that cuts a high frequency range regarded as a noise component, as compared with the case where a person under 40 years old uses it. become. In this case as well, since there are large individual differences, it is desirable for each user of the mobile communication terminal to switch to the optimum frequency characteristic that enables clear communication.

FIG. 6 is a curve showing the relationship between the cumulative noise years and the hearing ability. It is known that as the cumulative years of work in a noisy environment increase, the hearing loss near 4 kHz decreases. There is. Even in a mobile communication terminal used by such a hearing-impaired person, it is desirable to switch frequency characteristics to enable clear communication as compared with a case where a hearing-impaired person uses it. Even in this case, the preferable frequency characteristic has a large individual difference.

FIG. 7 is an explanatory diagram of frequency characteristics of the acoustic control filter. A solid curve A emphasizes a relatively flat frequency characteristic, a dotted curve B emphasizes a low frequency range, and a chain line C emphasizes a high frequency range. The frequency characteristic and the chain double-dashed curve D show the outline of the frequency characteristic that emphasizes the midrange. Further, it is possible to include a bimodal frequency characteristic for emphasizing the low frequency region and the high frequency region, a notch filter characteristic for cutting off a specific frequency, or a frequency characteristic corresponding to the hearing characteristic shown in FIGS.

The switching control signal is, for example, A, B,
The frequency characteristic curves of C and D can be selected, and the filter coefficient memory 18 of FIG.
Can be configured to read the filter coefficient by using the switching control signal designating the frequency characteristic curves A, B, C and D as an address. In this case, the switching control signal can be input by using the display of the mobile communication terminal and enabling the input operation according to the displayed guidance or the like.

FIG. 8 is an explanatory view of a main part of the second embodiment of the present invention. The same reference numerals as those in FIG. 2 indicate the same parts, 19a is a variable gain amplifier by a digital circuit, and 20a is a gain storing gain information. Information memory, acoustic control filter 1
The case where all 3 are configured by digital circuits is shown.
Therefore, the output signal of the acoustic control filter 13 is converted into an analog signal by the DA converter (D / A) 12 and applied to the receiver.

The filter unit 15 is the same as the filter unit 15 in FIG. 2, and the variable gain amplifier 19a by a digital circuit converts the digital output signal of the digital filter 17 into the digital gain read from the gain information memory 20a. It can be realized by a structure for multiplying information. The acoustic control filter 13 can be easily integrated into a circuit because it is configured by a digital circuit, and can also be realized by using the arithmetic function of a digital signal processor (DSP).

FIG. 9 is an explanatory view of the essential portions of the third embodiment of the present invention, in which 33 is an acoustic control filter, 35 is an analog filter, 36 is an output control unit, 37 is a variable gain amplifier, and 38.
Shows a gain information memory, and shows a portion corresponding to the acoustic control filter 3 of FIG. In this embodiment, the filter unit 5 is composed of an analog filter 35, and the output control unit 6 is composed of a variable gain amplifier 37 composed of an analog circuit. The analog filter 35 can be configured to control the selection or the attenuation amount of a combination of a plurality of filters having different filter constants such as resistors, capacitors, and inductances or center frequencies, and an attenuator according to the switching control signal. . Thereby, a desired frequency characteristic can be given to the input signal.

Further, the gain information memory 3 is selected by the switching control signal.
The gain information is read from 8 and applied to the variable gain amplifier 37. When the average value of the output power of the analog filter 35 changes due to the frequency switching by the switching control signal, the variable gain amplifier 37 corresponds to the read gain information. Since the output signal of the analog filter 35 is amplified by
It is possible to control so that the output volume does not change due to the frequency characteristic switching. Therefore, the operability is improved.

FIG. 10 is an explanatory view of an example of an analog filter, 41 is a branch circuit, 42 is a filter circuit section, and 43.
The combining circuit, 44 is a control circuit, 45 ₁ to 45 _n is an analog filter circuit, 46 ₁ -46 _n is the level adjustment circuit.

The analog filter circuits 45 _{1 to} 45 _n are
Each of them has a characteristic of a band pass filter having a different center frequency, and the input signals are converted into analog filter circuits 45 _{1 to} 45.
_The frequency bands are divided into different frequency bands according to _n , the levels are adjusted by the level adjusting circuits 46 _{1 to} 46 _n , and combined by the combining circuit 43.

The level adjusting circuits 46 _{1 to} 46 _n are controlled by the control circuit 44 to which the switching control signal is added. For example, when the frequency characteristics of the solid curve A in FIG. 46 _{1 to} 46 _n are controlled to have the same output level, and when the frequency characteristic of the dotted curve B is used, the output level of the level adjusting circuit corresponding to the analog filter circuit with the center frequency at the low frequency side is increased. However, the output level of the level adjusting circuit corresponding to the analog filter circuit on the high frequency side is controlled to be low.

FIG. 11 is an explanatory view of the main part of the variable gain amplifier, where 45 is an analog filter, 46 is a variable gain amplifier,
47 is a gain information memory, 48 is an operational amplifier, 49, 50
Is resistance. The variable gain amplifier 46 includes resistors 49,
Assuming that R ₁ and R ₂ are 50, an inverting amplifier in which the gain g is expressed by g = −R ₂ / R ₁ (1) is shown.

Since this gain g can be changed by changing the resistance 50, the frequency characteristic of the analog filter 45 is changed by the switching control signal as described above.
Switching is performed by switching the filter constant, level adjustment of the level adjusting circuit, or the like, and at the same time, the resistor 50 (R ₂ ) is changed according to the gain information read from the gain information memory 47. Thereby, the frequency characteristic of the analog filter 45 can be switched and the output volume of the handset can be made constant. Alternatively, the resistance value can be changed according to the gain information by using the resistance 49 (R ₁ ) as a variable resistance. Further, both the resistors 49 and 50 can be changed. Resistance 4
9 and 50 can also be configured by elements such as FET (field effect transistor) having a gate for adding gain information. Also, a variable gain amplifier having frequency characteristics can be constructed by adding a capacitor or the like and switching the capacitor or the resistance or the like according to the gain information.

FIG. 12 is an explanatory view of the essential portions of the fourth embodiment of the present invention. 51 is an output power control circuit, 52 is a power calculation circuit, 53 is a gain calculation circuit, 55 is a digital filter,
56 is a variable gain amplifier, 57 is a DA converter (D / A),
Reference numeral 58 denotes a filter coefficient memory, which shows a portion corresponding to the acoustic control filter 3 in FIG. 1, the filter unit 5 is configured by the digital filter 55 and the filter coefficient memory 58, and the output control unit 6 is configured by the variable gain amplifier 56. Then
An output power control circuit 51 is provided for controlling the gain of the variable gain amplifier 56.

The output signal to which the input signal is added and the desired frequency characteristic is given by the digital filter 55 is D
The signal is converted into an analog signal by the A converter 57 and is input to the variable gain amplifier 56 including an analog circuit. Further, the digital filter 55 has a frequency characteristic corresponding to the filter coefficient read from the filter coefficient memory 58 by the switching control signal. The input signal x _i and the output signal y _{i in} that case are converted into the power calculation circuit 52 of the output power control circuit 51.
In addition, the average power ratio is calculated and used as the correction coefficient K. That is, K = (Σx _i ² / Σy _i ² ) ^1/2 (2) is obtained.

The gain calculation circuit 53 calculates the gain of the variable gain amplifier 56 based on this correction coefficient K. Therefore, if the ratio of the average value of the input power and the average value of the output power of the digital filter 55 due to the switching of the frequency characteristics of the digital filter 55 becomes large, the gain of the variable gain amplifier 56 becomes large, and conversely If becomes smaller, the gain can be made smaller and the output volume of the handset can be made constant. In this case, the case where the average power ratio is used as the correction coefficient K is shown, but the difference between the average value of the input power and the average value of the output power is obtained as the correction coefficient K, and the variable gain amplifier 56 in the gain calculation circuit 53 is obtained. It is also possible to calculate the gain of. Further, the output power control circuit 51 can be easily realized by the arithmetic function of a digital signal processor (DSP), for example.

FIG. 13 is an explanatory view of the essential portions of the fifth embodiment of the present invention. 61 is an output power control circuit, 62 is a power calculation circuit, 63 is a gain calculation circuit, 65 is an analog filter, and 6
Reference numeral 6 denotes a variable gain amplifier, which is the acoustic control filter 3 of FIG.
The filter unit 5 is composed of an analog filter 65, and the output control unit 6 is a variable gain amplifier 6.
6 shows a case in which the output power control circuit 61 is provided.

The power calculation circuit 62 of the output power control circuit 61
Calculates the average value of the input power and the average value of the output power of the analog filter 65, calculates the ratio or difference between the average values, and adds the calculated ratio or difference to the gain calculation circuit 63. The gain calculation circuit 63 uses the variable gain amplifier 66 when the ratio or difference of the average values is large.
The gain is controlled to be large. Therefore, it is possible to eliminate the change in the output volume when the frequency characteristic is switched by the switching control signal. Therefore, the operability is improved.

FIG. 14 is an explanatory view of the essential portions of the sixth embodiment of the present invention. 61a is an output power control circuit, 62a is a power calculation circuit, 63a is a gain calculation circuit, 65a is a digital filter, and 66a is a variable gain. 1, which is an amplifier and corresponds to the acoustic control filter 3 in FIG. 1. The filter unit 5 is composed of a digital filter 65a, the output control unit 6 is composed of a variable gain amplifier 66a, and an output power control circuit 61a is provided. The variable gain amplifier 66a is
The digital output signal of the digital filter 65a may be multiplied by the digital gain from the gain calculation circuit 63a. Further, the output signal of the variable gain amplifier 66a is DA-converted and added to the receiver. Also in this embodiment, similarly to the embodiment shown in FIG. 13, it is possible to eliminate the change in the output volume when the frequency characteristic is switched.

FIG. 15 is an explanatory view of the essential portions of the seventh embodiment of the present invention, in which 71 is an output power control circuit, 72 is a power calculation circuit, 73 is a gain calculation circuit, 74 is a buffer memory, and 75 is a buffer memory.
Is a digital filter, 76 is a variable gain amplifier, 77 is a DA converter (D / A), 78 is a filter coefficient memory, 7
Reference numeral 9 is a delay circuit, and shows a portion corresponding to the acoustic control filter 3 in FIG.

An input signal from the signal processing unit of the mobile communication terminal (not shown) is input to the digital filter 75 and the power calculation unit 72 of the output power control circuit 71 via the buffer memory 74, and the digital filter 75 is The switching control signal has a frequency characteristic according to the filter coefficient read from the filter coefficient memory 78, and the output signal of the digital filter 75 is passed through the delay circuit 79 and the DA converter 77 to the variable gain amplifier 76 as an analog signal. The power calculation circuit 72 of the output power control circuit 71 receives the input signal and the output signal of the digital filter 75.
Is input to The output signal of the variable gain amplifier 76 is applied to a receiver (not shown).

Power calculation circuit 72 of output power control circuit 71
Is an average power ratio or average power difference between one frame length of the input signal via the buffer memory 74 and the corresponding output signal of the digital filter 75, and based on the average power ratio or average power difference, The gain calculation circuit 73 calculates the gain of the variable gain amplifier 76.

FIG. 16 is a diagram for explaining the operation of the seventh embodiment of the present invention. (A) is an input signal, (b1), (b2),
(B3) and (b4) show frames to be calculated. Further, (c) shows the arithmetic processing in the output power control circuit 71, and (d) shows the gain control of the variable gain amplifier 76.

The input signal of the frame length L and the output signal of the digital filter 75 of the frame length L corresponding thereto are input from the buffer memory 74 to the power calculation circuit 72, and the average value of the input power and the output power is calculated. Calculate the ratio or difference between the calculation and its average value. This calculation process is performed every frame period F (where F ≦ L). That is, for each frame period F, the ratio or difference between the average value of the input power and the average value of the output power for the frame length L is calculated, and the gain calculation circuit 73 calculates the gain as shown in FIG. g ₁ , g ₂ ,
Calculate g ₃ , ...

The delay circuit 79 includes a digital filter 75.
Output signal is delayed according to the processing time in the output power control circuit 71. In the configuration shown in the figure, the digital signal is delayed, and the delay time in this case is the delay of the gate circuit. It can be obtained by connecting a plurality of gate circuits by utilizing time, or can be obtained by selecting the frequency of the clock signal and the number of stages of flip-flops. Output power control circuit 7
It is also possible to select the delay time in consideration of the timing at which gain information is obtained from the gain calculation circuit 73 of 1 and the timing of the signal input to the variable gain amplifier 76.

It is also possible to provide a delay circuit 79 between the DA converter 77 and the variable gain amplifier 76. In that case, the analog signal is delayed, and therefore various already known analog signals are used. The delay circuit can be applied. The signal delayed by the delay circuit 79 is shown in (d). The gains g ₁ , g ₂ , g ₃ , ... For each frame period F calculated by the gain calculation circuit 73.
Thus, the variable gain amplifier 76 amplifies the output signal of the digital filter 75, so that the output volume of the receiver can be made constant.

In this case, the average power is calculated for the input signal and the output signal of the frame length L for each frame period F. The frame length L is made sufficiently longer than the pitch period of the voice signal. It is a thing. In that case, it is also possible to adopt a configuration in which the average power is obtained for the result of multiplication by the window function. That is, the gains g ₁ , g ₂ , g ₃ , ... Calculated by the gain calculation circuit 73 are controlled so that the average power is calculated so as to be almost constant when the frequency characteristics are not switched.

FIG. 17 is an explanatory view of the essential parts of the eighth embodiment of the present invention, showing the case where the variable gain amplifier 80 is constituted by a digital circuit, and the same reference numerals as those in FIG. 16 denote the same parts. Further, the output signal of the variable gain amplifier 80 is converted into an analog signal by a DA converter (not shown) and added to the receiver.

In the output power control circuit 71, the average value of the input power and the output power of the digital filter 75 is calculated by the power calculation circuit 72 for each frame period F with respect to the frame length L, as in the above-described embodiment. The average value ratio or difference is calculated, and the gain applied to the variable gain amplifier 80 in the gain calculation circuit 73 is calculated. Thereby, the output volume when the frequency characteristic is switched according to the switching control signal can be made constant.

The present invention is not limited to the above-described embodiments, but various additions and modifications can be made. For example, the variable gain amplifier is an amplifier for various analog signals other than the operational amplifier. Can be applied. As the digital variable gain amplifier, not only the structure of the multiplier but also the structure of the adder can be applied. Further, a changeover switch dedicated to the frequency characteristic changeover may be provided on the operation surface of the casing of the mobile communication terminal.

[0056]

As described above, according to the present invention, when the operating environment and operating conditions of the mobile communication terminal greatly differ even during use, the handset can be used even if the frequency characteristic is switched to an easily audible frequency characteristic. Since the output volume of does not change, there is an advantage that operability is improved. Therefore, even when it is used by various hearing-impaired persons such as elderly people, there is an advantage that it can be easily switched to a state where it is easy to hear.

Further, the frequency characteristic of the acoustic control filter 3 is switched by the switching control signal, and the variable gain amplifier of the output control section 6 is controlled by the gain information read from the gain information memory. There is an advantage that the output volume of the handset 4 can be made constant by switching the frequency characteristics.

Further, the gain of the variable gain amplifier of the output control unit 6 is controlled by obtaining the ratio or difference of the average value of the input power and the output power of the digital filter or the analog filter of the acoustic control filter 3. There is an advantage that the output volume of the handset 4 can be made constant by switching the frequency characteristic of the acoustic control filter 3 by compensating for the secular change of the characteristic of the acoustic control filter 3.

[Brief description of drawings]

FIG. 1 is a diagram illustrating the principle of the present invention.

FIG. 2 is an explanatory view of a main part of the first embodiment of the present invention.

FIG. 3 is an explanatory diagram of an example of a digital filter.

FIG. 4 is an equal loudness curve diagram.

FIG. 5 is a relationship curve diagram between age and hearing ability.

FIG. 6 is a relationship curve diagram between cumulative noise years and hearing ability.

FIG. 7 is an explanatory diagram of frequency characteristics of the acoustic control filter.

FIG. 8 is an explanatory diagram of a main part of a second embodiment of the present invention.

FIG. 9 is an explanatory diagram of a main part of a third embodiment of the present invention.

FIG. 10 is an explanatory diagram of an example of an analog filter.

FIG. 11 is an explanatory diagram of a main part of a variable gain amplifier.

FIG. 12 is an explanatory view of a main part of a fourth embodiment of the present invention.

FIG. 13 is an explanatory view of a main part of a fifth embodiment of the present invention.

FIG. 14 is an explanatory view of a main part of a sixth embodiment of the present invention.

FIG. 15 is an explanatory diagram of a main part of a seventh embodiment of the present invention.

FIG. 16 is an operation explanatory diagram of the seventh embodiment of the present invention.

FIG. 17 is an explanatory view of a main part of an eighth embodiment of the present invention.

[Explanation of symbols]

 1 Radio Receiver 2 Signal Processor 3 Acoustic Control Filter 4 Handset 5 Filter 6 Output Controller 7 Transmitter / Receiver 8 Antenna 9 Radio Transmitter 10 Signal Processor 11 Transmitter

Claims (5)

[Claims] 1. A mobile communication terminal having at least a wireless reception unit, a signal processing unit, an acoustic control filter for giving a desired frequency characteristic to a received voice signal, and a handset, wherein the acoustic control filter is A mobile communication characterized by comprising: a filter unit for switching frequency characteristics by a switching control signal; and an output control unit for switching and amplifying a gain so that the output volume does not change in response to the frequency characteristic switching of the filter unit. Terminal. 2. The acoustic control filter includes a filter section and an output control section, the filter section having a filter coefficient memory for reading a filter coefficient according to a switching control signal, and a frequency according to the filter coefficient read from the filter coefficient memory. A digital filter for switching characteristics, the output control unit does not change output volume due to switching of frequency characteristics due to gain information memory for reading gain information by the switching control signal, and gain information read from the gain information memory. 2. The mobile communication terminal according to claim 1, further comprising a variable gain amplifier that controls the gain to amplify the output signal of the filter unit. 3. The acoustic control filter includes a filter section and an output control section, the filter section includes an analog filter that switches a filter constant by a switching control signal to switch frequency characteristics, and the output control section includes the analog filter. A gain information memory that reads the gain information by the switching control signal, and a gain information that is read from the gain information memory, controls the gain so that the output volume does not change due to the frequency characteristic switching, and amplifies the output signal of the filter unit. The mobile communication terminal of claim 1, further comprising a variable gain amplifier. 4. The acoustic control filter includes a filter section that switches frequency characteristics according to a switching control signal, an output control section that amplifies and outputs an output signal of the filter section, and an output power control circuit. The power control circuit includes a configuration for controlling the output control unit based on the average value of the input power and the average value of the output power of the filter unit so that the output volume change due to the frequency characteristic switching does not occur. The mobile communication terminal according to claim 1, wherein the mobile communication terminal is a mobile communication terminal. 5. The acoustic control filter comprises at least one
A buffer memory that stores the input signal for the frame length,
A digital filter for adding the input signal via the buffer memory, a filter coefficient memory for reading out a filter coefficient for switching the frequency characteristic of the digital filter by a switching control signal, and a variable gain for amplifying the output signal of the digital filter. An amplifier and an output power control circuit that controls the gain of the variable gain amplifier based on the average value of the input power and the average value of the output power of the digital filter, the output power control circuit comprising: For a predetermined frame length of an input signal, for each frame period shorter than the frame length, a power calculation circuit for obtaining a ratio or a difference between the average value of the input power and the average value of the output power, and an output signal of the power calculation circuit. And a gain calculation circuit for correspondingly calculating the gain of the variable gain amplifier. Item 1. A mobile communication terminal according to item 1 or 4.