JP2010010954A - Voice amplification device, voice output device, projector, power monitoring method, power monitoring program, and recording medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide: a voice amplification device capable of suppressing overload on a loudspeaker and degradation in sound quality; a voice output device; a projector; a power monitoring method; a power monitoring program; and a recording medium. <P>SOLUTION: A voice amplification device (projector) 1, amplifying and outputting a voice signal, includes: an amplifying means (voice amplification part ) 82 which amplifies an inputted voice signal by a set amplification rate for output; a detecting means 6 which detects a power level of the voice signal outputted from the amplifying means 82; and a control means (control part) 83 which, based on the power level detected with the detecting means 6, fluctuates the amplification rate of the voice signal by the amplifying means 82. Thus, an overload is discouraged to occur at a loudspeaker, and since the voice signal inputted to the amplifying means 82 does not change, no degradation occurs in output voice even if the voice signal is amplified. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a sound amplifying device that amplifies and outputs a sound signal, a sound output device, a projector, a power monitoring method used in the sound amplifying device, a power monitoring program, and a recording medium.

  2. Description of the Related Art Conventionally, there has been known a projector that modulates a light beam emitted from a light source device according to an input image signal to form image light, and enlarges and projects the image light on a projection surface such as a screen. As such a projector, a projector including a speaker that outputs a sound corresponding to a sound signal input from an external device such as a player is known.

  By the way, rated power is set for the speaker. This is because the coil, the cone, and the like constituting the speaker are damaged when power exceeding the rated power is input as an audio signal for a long time. In particular, inexpensive speakers tend to be damaged by excessive power input, and it is necessary to perform control so that power exceeding the rated power is not input for a long time when sound is output from the speaker. In response to such a need, there is known a power amplifying apparatus that reduces a power value of a sound signal output to a speaker when the power value exceeds a predetermined value (see, for example, Patent Document 1).

  In the power amplifying device described in Patent Document 1, a power amplifying circuit and a limiter are provided for each channel of the input audio signal, and an input signal or an output signal of each power amplifying circuit is measured, Calculate the output power of the channel. When the calculated value exceeds the power supply capacity, the output power from the power amplifier circuit is reduced by controlling the amplitude of the input signal to each power amplifier circuit with a limiter. With such a configuration, excessive power is not output to the speaker, and damage to the speaker can be prevented.

JP 2002-198756 A

  However, in the power amplifying device described in Patent Document 1, the amplitude of the audio signal input to the power amplifier circuit of each channel is limited by the limiter, so that the input signal to the power amplifier circuit is distorted. For this reason, there is a problem that the sound quality deteriorates and it becomes difficult to hear, such as noise being output as sound or the balance of sound being lost.

  An object of the present invention is to provide an audio amplifying device, an audio output device, a projector, a power monitoring method, a power monitoring program, and a recording medium that can suppress overload on a speaker and deterioration in sound quality.

  In order to achieve the above-described object, the audio amplifying apparatus of the present invention is an audio amplifying apparatus that amplifies and outputs an audio signal, and amplifies and outputs the input audio signal at a set amplification factor. Amplifying means; detecting means for detecting the power level of the audio signal output from the amplifying means; and varying the amplification factor of the audio signal by the amplifying means based on the power level detected by the detecting means. And a control means for making it possible.

  According to the present invention, the control means varies the amplification factor based on the power level of the audio signal output from the amplification means. According to this, for example, when the power level of the audio signal output from the amplifying unit is larger than the rated power of the speaker, the power level of the output signal from the amplifying unit is reduced by reducing the amplification factor. Can be reduced. At this time, the control means can reduce the amplification factor of the audio signal at the amplifying means, so that the audio signal can be input to the amplifying means without being deteriorated. And can output. Therefore, since the power level of the output audio signal can be lowered, it is possible to prevent the speakers connected to the audio amplifying apparatus from being overloaded and damaged, and to suppress deterioration in sound quality. be able to.

  In the present invention, the control unit calculates an average power value within a predetermined period of the audio signal output from the amplification unit based on the power level detected by the detection unit; A power value determination unit that determines whether or not the calculated average power value exceeds a reference value corresponding to the predetermined period, and the power value determination unit determines that the average power value exceeds the reference value Then, it is preferable to include an amplification factor control unit that lowers the amplification factor.

Here, even when power that is equal to or higher than the rated power is input to the speaker, the speaker is often not damaged for a short time. For example, in a speaker having a rated power of 10 W, even if 20 W power is input for a short time, it is allowed, and no damage occurs even if 30 W power is input for a shorter time. Conversely, if 15 W of power is input for a long time, the speaker may be damaged. Such a tendency is more conspicuous for cheaper speakers.
On the other hand, in the present invention, when the power value determination unit determines that the average power value of the predetermined period calculated by the average value calculation unit exceeds the reference value, the amplification factor control unit decreases the amplification factor. According to this, by comparing the average power value with the reference value, a large power output from the amplifying means is allowed for a short time. Therefore, an inexpensive speaker can be used effectively so that damage does not occur.

  In the present invention, storage means for storing a table in which an intensity ratio between the audio signal input to the amplifying means and the audio signal amplified by the amplifying means is associated with an amplification factor that realizes the intensity ratio. And the amplification factor control unit sets the intensity ratio to a value obtained by reducing the set intensity ratio by a predetermined value when the power value determination unit determines that the average power value exceeds the reference value. It is preferable to include a setting unit, an amplification factor acquisition unit that acquires the amplification factor according to the set intensity ratio from the table, and an operation control unit that operates the amplification unit with the acquired amplification factor. .

Such an intensity ratio can be expressed in decibels (dB).
According to the present invention, when the average power value for a predetermined period exceeds the reference value, the intensity ratio setting unit sets an intensity ratio that is a predetermined value lower than the currently set intensity ratio, and the amplification factor setting unit An amplification factor corresponding to the intensity ratio is acquired from a table stored in the storage unit. According to this, since the amplifying unit is operated at the amplification factor by the operation control unit, the processing in the audio amplifying device can be simplified as compared with the case of calculating the amplification factor, and output from the amplifying unit. The power value of the audio signal to be played can be reliably reduced.
Further, even when the speaker connected to the audio amplifying device is changed, it can be dealt with by changing only the table stored in the storage means, and the versatility of the audio amplifying device can be improved.

  In the present invention, the detection means detects the power level by detecting the voltage of the audio signal output from the amplification means, and the control means is based on the voltage detected by the detection means. A power value calculation unit that calculates a power value of the audio signal output from the amplification unit, the average value calculation unit based on the power value calculated by the power value calculation unit It is preferable to calculate the power value.

  Here, when detecting the electric power level, the configuration becomes complicated, for example, in order to detect the current value, it is necessary to provide an ammeter in series. On the other hand, in the present invention, the detection means detects the voltage value, so that the voltage value can be detected by connecting the voltmeter in parallel, so that the configuration of the audio amplifying device can be simplified. Not only can the power level be detected without loss of power.

According to another aspect of the present invention, there is provided an audio output device comprising: the above-described audio amplifying device; and a speaker that outputs audio corresponding to an audio signal output from the audio amplifying device.
According to the present invention, the same effects as those of the above-described audio amplifying apparatus can be obtained, and control according to the rated power (allowable power) of the connected speaker is possible.

The projector of the present invention is a projector including a light source device, a light modulation device that modulates a light beam emitted from the light source device to form image light, and a projection optical device that projects the image light. And an audio output device as described above.
According to the present invention, it is possible to achieve the same effect as the above-described audio output device. In addition, since the projector can easily display a large image, the projector is widely used when used by a small number of people or used by a large number of people, and the volume of sound output from a speaker is large. For this reason, the power input to the speaker may become large depending on the use state, but as described above, the power is particularly suitable because the overload of the speaker is suppressed due to the fluctuation of the amplification factor. .

In the present invention, it is preferable that the control means includes display means for performing a display indicating that the amplification factor is changed when the amplification factor is changed.
According to the present invention, when the amplification factor of the amplification unit is changed by the control unit and the power value of the audio signal input to the speaker is changed, the display unit displays the amplification factor. It is. According to this, when there is a change in the sound output from the speaker, it is possible to make the user recognize that the change has occurred in order to suppress overload. Therefore, the convenience of the projector can be improved.

The power monitoring method of the present invention is a power monitoring method for monitoring a power level of an audio signal output from the audio amplifying device, which is used in an audio amplifying device that amplifies and outputs an audio signal. A detection step of detecting a power level of the audio signal amplified at a predetermined amplification rate, and the audio signal at a gain reduced by a predetermined value from the set amplification rate based on the detected power level. And an amplification step for amplifying.
According to the present invention, it is possible to achieve the same effects as those of the above-described audio amplifying device.

The power monitoring program of the present invention is a power monitoring program that is executed by an audio amplifying apparatus that amplifies and outputs an audio signal, and that monitors the power level of the audio signal output from the audio amplifying apparatus. A detection step of detecting a power level of the audio signal amplified at a predetermined amplification rate, and the audio signal at a gain reduced by a predetermined value from the set amplification rate based on the detected power level. And an amplification step for amplifying.
According to the present invention, it is possible to achieve the same effect as the power monitoring method described above.

The recording medium of the present invention is characterized in that the above-described power monitoring program is recorded so as to be readable by a computer.
According to the present invention, the sound amplifying apparatus reads the power monitoring program from the recording medium and executes it, so that the same effect as the above-described power monitoring program can be obtained.
As recording media, magnetic tapes such as DAT (Digital Audio Tape), magnetic disks such as FD (Flexible Disc), optical disks such as CD (Compact Disc) and DVD (Digital Versatile Disc), magneto-optical disks, hard disk devices, In addition, a semiconductor memory or the like can be used, and the power monitoring program can be installed, executed, and distributed using these.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
[Configuration of projector]
FIG. 1 is a block diagram showing a configuration of a projector 1 according to the present embodiment.
The projector 1 modulates a light beam emitted from the light source device according to an image signal input from the connected image signal output device 91 to form image light, and the image light is projected on a projection surface such as a screen. Enlarged projection. In addition, the projector 1 amplifies an audio signal input from the connected audio signal output device 92 and outputs audio corresponding to the audio signal through a built-in speaker. Note that the image signal output device 91 and the audio signal output device 92 may be configured as an integrated external device.

  As shown in FIG. 1, the projector 1 includes an operation panel 2, a receiving unit 3, an image forming unit 4, a speaker 5, a detecting unit 6, an LED (Light Emitting Diode) 7, and a control unit 8. Although not shown in detail, the projector 1 includes a power supply unit that supplies power to the electronic components that constitute the projector 1, a cooling unit that includes a fan and the like.

The operation panel 2 is provided with a plurality of keys for operating the projector 1 and is exposed on the outer surface of the projector 1. The operation panel 2 outputs an operation signal corresponding to the key input by the user to the control means 8. As such keys, a power key for turning on / off the power, a volume adjusting key for setting a volume (decibel (dB)) output from a speaker, and the like are provided.
The receiving unit 3 digitally converts the infrared signal transmitted from the remote controller 93 and outputs the converted signal (operation signal) to the control unit 8. Such a remote controller 93 is provided with a key similar to the key provided on the operation panel 2, and transmits an operation signal corresponding to the input key to the projector 1 as an infrared signal.

The image forming unit 4 forms and projects image light corresponding to the drive signal input from the control unit 8. For example, the image forming unit 4 forms an image corresponding to the image signal input from the image signal output device 91 and lowers the power value of the audio signal input to the speaker 5 in the power monitoring process described later. An image indicating this is formed. That is, the image forming unit 4 corresponds to the display unit of the present invention. Such an image forming unit 4 includes a light source device 41, a light modulation device 42, and a projection optical device 43.
Among these, the light source device 41 includes a light source lamp such as a high-pressure mercury lamp or a solid light source such as an LED and a reflector that is a reflecting mirror, and irradiates the light modulation device 42 with a light beam.

The light modulation device 42 includes a liquid crystal panel and a driver that drives the liquid crystal panel. Among these, the liquid crystal panel controls the alignment state of the liquid crystal according to the drive signal input from the control means 8, thereby modulating the polarization direction of the incident light beam, and thereby image light corresponding to the drive signal. Is formed. Note that the light modulation device is not limited to a configuration including a liquid crystal panel, and a configuration other than liquid crystal, such as a device using a micromirror, may be employed.
The projection optical device 43 enlarges and projects the image light formed by the light modulation device 42 onto the projection surface, and is a combined lens including a lens barrel and a plurality of lenses housed in the lens barrel. It is configured.

  The speakers 5 are provided on the left and right sides of the projector 1, respectively, and output sound corresponding to the sound signal at a volume corresponding to the power value of the sound signal input from the control unit 8. The rated power of a predetermined wattage is set for these speakers 5, and the control means 8 to be described later executes a power monitoring process so that power exceeding the rated power is not input to the speakers 5 for a long time. Sets the power value of the audio signal output to the. The power monitoring process will be described later in detail.

The detection means 6 detects the voltage value of the audio signal input from the control means 8 to the speaker 5 and is connected in parallel to the signal line connecting the control means 8 and the speaker 5. The voltage value detected by the detection means 6 is acquired by the control means 8.
The LED 7 is turned on in response to an ON signal input from the control means 8 when the power value of the audio signal input to the speaker 5 is lowered in the power monitoring process described later, thereby preventing overloading of the speaker 5. Therefore, the user is notified that the supply power value has been lowered. That is, the LED 7 corresponds to the display means of the present invention.

[Configuration of control means]
The control means 8 is configured as a circuit board on which a CPU (Central Processing Unit) and the like are mounted, and controls the entire projector 1. The control unit 8 includes a display control unit 81, an audio amplification unit 82, a control unit 83, and a memory 84. That is, the control means 8 and the detection means 6 constitute an audio amplification apparatus of the present invention, and the detection means 6 and the control means 8 and the above-described speaker 5 constitute an audio output apparatus of the present invention.

  Among these, the memory 84 corresponds to the storage means of the present invention, and includes a ROM (Read Only Memory) and a RAM (Random Access Memory). The memory 84 functions as a work memory of the control unit 83 and stores various programs and data necessary for controlling the projector 1 by the control unit 83.

  For example, as such a program, the memory 84 stores a power monitoring program for executing a power monitoring process described later. Further, as data, the memory 84 has an intensity ratio (decibel (dB)) between the audio signal input from the audio signal output device 92 and the audio signal output to the speaker 5 and audio for realizing the intensity ratio. An LUT (Look Up Table) associated with the signal amplification factor is stored. This intensity ratio corresponds to the volume set by the user and output from the speaker 5.

  Further, the memory 84 has a criterion that the average power value of the audio signal input to the speaker 5 should not exceed a predetermined period (in this embodiment, 0.5 second, 1 second, 2 seconds, 4 seconds, and 60 seconds). The values (Pmax (0.5), Pmax (1), Pmax (2), Pmax (4) and Pmax (60), respectively) are stored. Note that these reference values are set to 30 W, 25 W, 20 W, 15 W and 10 W, respectively, according to the rated power since the rated power of the speaker 5 is 10 W in this embodiment. The power value and period can be set as appropriate.

  The display control unit 81 processes the image signal input from the above-described image signal output device 91 under the control of the control unit 83, and generates image data for one screen on a frame buffer (not shown). The display control unit 81 generates image data related to a message indicating that the power of the audio signal input to the speaker 5 has been reduced when a control signal is input from the notification unit 838 constituting the control unit 83. To do. Then, the display control unit 81 outputs a drive signal corresponding to the image data to the light modulation device 42 of the image forming unit 4 to form and display the image.

[Configuration of audio amplifier]
FIG. 2 is a block diagram illustrating the configuration of the audio amplifying unit 82 and the control unit 83.
The audio amplifying unit 82 corresponds to the amplifying means of the present invention, and amplifies an audio signal input from the audio signal output device 92 via an input terminal (not shown). As shown in FIG. 2, the audio amplifying unit 82 includes a preamplifier 821 that adjusts the tone and left / right balance of the input audio signal, and a power amplifier 822.
Among these, the power amplifier 822 amplifies the audio signal input from the preamplifier 821 at the amplification factor input from the control unit 83 as a parameter, and outputs the amplified audio signal to the speaker 5. The voltage value of the audio signal output from the power amplifier 822 to the speaker 5 is detected by the detection unit 6 as described above.

(Configuration of control unit)
The control unit 83 corresponds to the control means of the present invention and controls the entire projector 1. Specifically, the control unit 83 autonomously controls the projector 1 in addition to performing processing according to operation signals input from the operation panel 2 and the receiving unit 3. For example, the control unit 83 causes the display control unit 81 to generate image data of the set color when an operation signal for setting the color of the display image is input. Further, when an operation signal for changing the volume output from the speaker 5 is input, an amplification factor corresponding to the changed volume is output to the power amplifier 822. Furthermore, the control unit 83 monitors the power value of the audio signal input to the speaker 5 and controls the operation of the audio amplifying unit 82 so that the average power value within a predetermined period does not exceed the reference value. Process.

As shown in FIG. 2, the control unit 83 includes a voltage value acquisition unit 831, a power value calculation unit 832, an average value calculation unit 833, a power value determination unit 834, an intensity ratio setting unit 835, and an amplification factor acquisition unit 836. , An operation control unit 837 and a notification unit 838 are provided.
The voltage value acquisition unit 831 acquires the voltage value detected by the detection unit 6.
The power value calculation unit 832 calculates the power value of the audio signal input to the speaker 5 from the acquired voltage value. The calculated power value is sequentially stored in the memory 84.
The average value calculation unit 833 calculates an average power value within the latest predetermined period from the calculated power value. Specifically, the average value calculation unit 833 calculates the average power values for the latest 0.5 seconds, 1 second, 2 seconds, 4 seconds, and 60 seconds (A (0.5), A (1), A (2), respectively). , A (4) and A (60)).

The power value determination unit 834 acquires a reference value (Pmax) for the same period as each calculated average power value from the memory 84, and determines whether the average power value exceeds the reference value.
At this time, the power value determination unit 834 first determines whether the average power value (A (0.5)) for the last 0.5 seconds exceeds the same reference value (Pmax (0.5)) for 0.5 seconds. If not, it is determined whether or not the average power value (A (1)) for the last one second exceeds the reference value (Pmax (1)) for the same one second. If not, it is determined whether or not the average power value (A (2)) for the last 2 seconds exceeds the reference value (Pmax (2)) for 2 seconds. In the same manner, the average power value (A (4)) for the last 4 seconds and the reference value (Pmax (4)) are compared in the same way, and the average power value (A (60)) for the last 60 seconds and the reference are compared. Compare the value (Pmax (60)).

  The intensity ratio setting unit 835 determines the audio signal output to the speaker 5 with respect to the audio signal input to the audio amplifying unit 82 when the power value determination unit 834 determines that the average power value exceeds the reference value. Reduce the intensity ratio. Specifically, the intensity ratio setting unit 835 newly sets an intensity ratio that is 1 dB lower than the currently set intensity ratio. As a result, the volume output from the speaker 5 is lowered by one level (one decibel). In the present embodiment, the intensity ratio setting unit 835 reduces the intensity ratio by 1 decibel. However, for example, the intensity ratio may be decreased by 0.5 decibel, and the value of the intensity ratio to be decreased can be set as appropriate. .

The amplification factor acquisition unit 836 acquires the amplification factor corresponding to the intensity ratio set by the intensity ratio setting unit 835 from the LUT stored in the memory 84.
The operation control unit 837 outputs the amplification factor acquired by the amplification factor acquisition unit 836 to the power amplifier 822 as a parameter, and causes the power amplifier 822 to operate at the amplification factor. Thus, the power amplifier 822 amplifies the audio signal so that the intensity ratio set by the intensity ratio setting unit 835 is obtained.
When the intensity ratio is reduced by the intensity ratio setting unit 835, that is, when the volume output from the speaker 5 is reduced, the notification unit 838 reduces the volume as an internal process rather than based on a user operation. Is notified. Specifically, the notification unit 838 outputs an ON signal to the LED 7 to turn on the LED 7, causes the display control unit 81 to generate the above-described image data, and outputs a drive signal corresponding to the image data to the image forming unit. 4 to output. As a result, a message indicating that the volume has been lowered is displayed as a projection image.

[Power monitoring processing]
FIG. 3 is a flowchart showing the power monitoring process.
When the projector 1 is turned on, the projector 1 reads a power monitoring program from the memory 84 and executes a power monitoring process according to the program. This power monitoring process is repeatedly executed several times per second as an interrupt process of the control unit 83.
In this power monitoring process, as shown in FIG. 3, first, the voltage value acquisition unit 831 of the control unit 83 acquires the voltage value of the audio signal detected by the detection means 6 (step S01), and the power value calculation unit 832 calculates the power value of the audio signal from the acquired voltage value, and stores the power value in the memory 84 (step S02). Thereafter, based on the power value stored in the memory 84, the average value calculation unit 833 determines the average power value (A (0.5), A (1), A (2), A (4) and A (60)) are calculated (step S03).

  Next, the power value determination unit 834 compares each average power value with each reference value stored in the memory 84. Specifically, the power value determination unit 834 first determines whether the most recent 0.5 second average power value (A (0.5)) exceeds the 0.5 second reference value (Pmax (0.5)). Is determined (step S04). If it is determined that the value does not exceed, the power value determination unit 834 causes the average power value (A (1)) for the last one second to exceed the reference value (Pmax (1)) for the same one second. It is determined whether or not (step S05). Similarly, when it is determined that the value does not exceed, the power value determination unit 834 causes the average power value (A (2)) for the last 2 seconds to exceed the reference value (Pmax (2)) for 2 seconds. It is determined whether or not (step S06).

If it is determined in step S06 that the value does not exceed, the power value determination unit 834 determines that the average power value (A (4)) for the last 4 seconds is the same as the reference value (Pmax for 4 seconds). It is determined whether or not (4)) is exceeded (step S07). If it is determined that the value does not exceed, the power value determination unit 834 further causes the average power value (A (60)) for the last 60 seconds to exceed the reference value (Pmax (60)) for 60 seconds. It is determined whether or not (step S08).
If it is determined in step S08 that it has not exceeded, the control unit 83 determines that the power value of the audio signal currently input to the speaker 5 is within the allowable range, Return to S01.

On the other hand, if it is determined in steps S04 to S08 that even one of the average power values exceeds the corresponding reference value, the intensity ratio setting unit 835 is currently set. An intensity ratio that is 1 decibel lower than the existing intensity ratio is newly set (step S09).
Then, the amplification factor acquisition unit 836 acquires the amplification factor corresponding to the set intensity ratio from the LUT stored in the memory 84 (step S10), and the operation control unit 837 amplifies the sound with the acquired amplification factor. The power amplifier 822 of the unit 82 is operated (step S11). Thereby, since the amplification factor of the audio signal in the power amplifier 822 is lowered, the power of the audio signal input to the speaker 5 is reduced.

  In addition to step S11, the notification unit 838 outputs an ON signal to turn on the LED 7, and also outputs a control signal to the display control unit 81 to display the above-described message on the image formed by the image forming unit 4. By doing so, the fact that the intensity ratio of the audio signal has been changed by the internal processing is notified (step S12). As a result, the user can recognize that a change in volume due to a change in output power to the speaker 5 has occurred.

The projector 1 according to the present embodiment described above has the following effects.
When the average power value of the audio signal input from the audio amplifying unit 82 to the speaker 5 is larger than the reference value, the intensity ratio setting unit 835 lowers the currently set intensity ratio by 1 decibel. Then, the operation control unit 837 operates the audio amplification unit 82 with the amplification factor acquired by the amplification factor acquisition unit 836, thereby reducing the power input to the speaker 5. According to this, since the audio signal input to the audio amplifying unit 82 does not change, it is possible to suppress the occurrence of distortion even if the audio signal is amplified. Therefore, it is possible to suppress overloading of the speaker 5 and to suppress deterioration of sound quality.

  Whether or not the power input to the speaker 5 is overloaded in the speaker 5 is determined by a determination process by the power value determination unit 834. The power value determination unit 834 determines that the speaker 5 may be overloaded when each average power value calculated by the average value calculation unit 833 exceeds the corresponding reference value. According to this, since a temporary overload in an allowable range in the speaker 5 is overlooked, the performance of the speaker 5 can be effectively utilized, and frequent reduction of the intensity ratio can be suppressed. Therefore, the inexpensive speaker 5 can be used effectively, and it is possible to reliably prevent the output sound from becoming difficult to hear.

  When the power value determination unit 834 determines that any one of the average power values exceeds the corresponding reference value, the amplification factor acquisition unit 836 sets the intensity ratio newly set by the intensity ratio setting unit 835. The corresponding amplification factor is acquired from the LUT stored in the memory 84. According to this, compared with the case where the amplification factor is calculated every time the set intensity ratio is changed, the processing of the control unit 83 can be simplified, and the audio signal output from the audio amplification unit 82 can be simplified. The power value can be reliably reduced. Even when the speaker 5 is changed, it is possible to cope with the performance of the speaker 5 only by changing the LUT of the memory 84, so that the versatility of the projector 1 can be improved.

  The detecting means 6 detects the voltage value of the audio signal when detecting the power level of the audio signal input to the speaker 5. According to this, compared with the case where the current value is detected, the power level can be easily detected without losing power, and the circuit configuration of the projector 1 can be simplified.

  When the power value determination unit 834 determines that the average power value has exceeded the reference value and the amplification factor of the power amplifier 822 of the audio amplification unit 82 is lowered, the LED 7 is lit under the control of the notification unit 838. In addition, a message is displayed by the display control unit 81 and the image forming unit 4. According to this, it is possible to make the user recognize that the decrease in volume caused by the decrease in the amplification factor is a change that occurs in order to suppress overload. Therefore, the convenience of the projector 1 can be improved.

[Modification of Embodiment]
The present invention is not limited to the above-described embodiment, and modifications, improvements, and the like within the scope that can achieve the object of the present invention are included in the present invention.
In the embodiment, the power value calculation unit 832 calculates a power value based on the voltage value detected by the detection unit 6, and the average value calculation unit 833 calculates an average power value within a predetermined period from the power value. Then, the power value determination unit 834 determines whether or not an overload occurs in the speaker 5 by comparing the calculated average power value and the reference value, but the present invention is not limited to this. That is, the power value determination unit determines whether or not the power value calculated by the power value calculation unit 832 exceeds a reference value (for example, rated power or a power value lower than the rated power). It may be determined whether or not an overload occurs. Further, the period of the average power value calculated by the average value calculation unit 833 is not limited to the above-described period, and may be set as appropriate.

  In the embodiment, the amplification factor acquisition unit 836 acquires the amplification factor according to the intensity ratio set by the intensity ratio setting unit 835 from the LUT stored in the memory 84, and the operation control unit 837 acquires the amplification factor. However, the present invention is not limited to this. That is, the amplification factor acquisition unit 836 may calculate the amplification factor according to the set intensity ratio. Further, although the audio amplifying unit 82 is configured to include the preamplifier 821 and the power amplifier 822, the present invention is not limited to this and may be configured to be integrated.

  In the above embodiment, the power monitoring program for executing the power monitoring process is stored in the memory 84 constituted by a ROM or the like. However, the present invention is not limited to this, and the present invention is not limited thereto. It may be recorded on a recording medium such as a magneto-optical disk and a hard disk device. In such a case, the above-described power monitoring process can be executed by the control means 8 reading the power monitoring program from these recording media as necessary.

  In the above embodiment, the projector 1 is exemplified, but the present invention is not limited to this, and can be used for an audio device such as a stereo or an amplifier.

  The present invention can be used not only for projectors but also for audio equipment such as stereos and amplifiers.

1 is a block diagram illustrating a configuration of a projector according to an embodiment of the invention. The block diagram which shows the structure of the audio | voice amplification part and control part in the said embodiment. The flowchart which shows the electric power monitoring process in the said embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Projector (audio | voice amplification apparatus, audio | voice output apparatus), 4 ... Image formation means (display means), 5 ... Speaker, 6 ... Detection means, 7 ... LED (display means), 41 ... Light source device, 42 ... Light modulation apparatus , 43... Projection optical device, 82... Sound amplifying unit (amplifying unit), 83... Control unit (control unit), 84... Memory (storage unit), 832 ... power value calculating unit, 833. Power value determination unit, 835... Intensity ratio setting unit (amplification rate control unit), 836... Gain acquisition unit (amplification rate control unit), 837... Operation control unit (amplification rate control unit).

Claims (10)

An audio amplification device that amplifies and outputs an audio signal,
Amplifying means for amplifying the input audio signal at a set amplification factor and outputting it;
Detecting means for detecting a power level of the audio signal output from the amplifying means;
A sound amplifying apparatus comprising: control means for varying the amplification factor of the sound signal by the amplifying means based on the power level detected by the detecting means. The sound amplifying device according to claim 1,
The control means includes
An average value calculation unit for calculating an average power value within a predetermined period of the audio signal output from the amplification unit based on the power level detected by the detection unit;
A power value determination unit that determines whether or not the calculated average power value exceeds a reference value corresponding to the predetermined period;
An audio amplification device comprising: an amplification factor control unit that reduces the amplification factor when the power value determination unit determines that the average power value exceeds the reference value. The sound amplifying device according to claim 2,
Storage means for storing a table in which an intensity ratio between the audio signal input to the amplifying means and the audio signal amplified by the amplifying means is associated with an amplification factor that realizes the intensity ratio;
The amplification factor controller
When the power value determination unit determines that the average power value exceeds the reference value, an intensity ratio setting unit that sets the set intensity ratio to a value reduced by a predetermined value;
An amplification factor acquisition unit for acquiring the amplification factor according to the set intensity ratio from the table;
An audio control apparatus comprising: an operation control unit that operates the amplifying unit with the acquired amplification factor. In the audio amplifying device according to claim 2 or 3,
The detection means detects the power level by detecting the voltage of the audio signal output from the amplification means,
The control means includes
Based on the voltage detected by the detection means, a power value calculation unit that calculates a power value of the audio signal output from the amplification means,
The average value calculation unit calculates the average power value based on the power value calculated by the power value calculation unit.   5. An audio output device comprising: the audio amplifying device according to claim 1; and a speaker that outputs audio corresponding to an audio signal output from the audio amplifying device. A projector comprising: a light source device; a light modulation device that modulates a light beam emitted from the light source device to form image light; and a projection optical device that projects the image light,
A projector comprising the audio output device according to claim 5. The projector according to claim 6, wherein
A projector comprising: display means for performing a display indicating that the amplification factor has changed when the amplification factor is changed by the control means. A power monitoring method that is used in a sound amplifying device that amplifies and outputs a sound signal, and that monitors a power level of the sound signal output from the sound amplifying device,
A detection step of detecting a power level of the audio signal amplified at a set amplification rate;
A power monitoring method comprising: an amplification step of amplifying the audio signal with an amplification factor that is a predetermined value lower than the set amplification factor based on the detected power level. A power monitoring program that is executed by a sound amplifying device that amplifies and outputs a sound signal, and that monitors a power level of the sound signal output from the sound amplifying device,
A detection step of detecting a power level of the audio signal amplified at a set amplification rate;
A power monitoring program comprising: an amplification step of amplifying the audio signal with an amplification factor that is a predetermined value lower than the set amplification factor based on the detected power level.   A recording medium in which the power monitoring program according to claim 9 is recorded so as to be readable by a computer.

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