JP2004021162A - Audio equipment, control method of audio equipment and audio equipment control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an audio equipment with design of simple operating method, interactive and new in appearance and to provide the audio equipment with probability that listening style of music is renewed. <P>SOLUTION: In the audio equipment 100, a reproduction signal of a CD 9 is signal processed by a DSP (digital signal processor), D/A converted, amplified and outputted by voice from a speaker section 5. The DSP comprises a RAM and performs acoustic processing to an input signal according to a program written in the RAM. A device 10 in the frustconial shape comprises a communication means and a memory in which a program to the DSP is preliminarily stored. When the device 10 is set on an installation part 7, the program is read from the memory of the device 10, transmitted to the audio equipment 100 by the communication means and written in the RAM of the DSP of the audio equipment 100. The acoustic processing of the DSP is changed according to the program written in the RAM. Acoustic characteristics of reproduced sound of the audio equipment 100 are changed simply by setting the device 10 on the installation part 7. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an acoustic device capable of interactively controlling acoustic characteristics, a method of controlling the acoustic device, and an acoustic device control device.
[0002]
[Prior art]
In recent years, audio signals have been treated as digitized audio data even in audio equipment, especially small stereo playback devices used at home, and adjustment of acoustic characteristics such as equalizer adjustment is also performed by digital control. It has become common. In digital audio equipment, control of audio characteristics of audio data is generally performed using a DSP (Digital Signal Processor).
[0003]
As a user interface for adjusting acoustic characteristics in such a digital audio device, for example, a user interface preset as a default or a user's own customized setting selected by a button or the like is mainly used. In many cases, the acoustic characteristics are manually adjusted using an interface simulating a conventional analog audio device such as a rotary knob or a slide bar. For example, the acoustic characteristics are controlled by changing predetermined parameters for a DSP programmed in advance by button selection or manual setting.
[0004]
[Problems to be solved by the invention]
In such a man-machine interface of an audio device, an operation method different from the conventional operation method has not been provided. In addition, there is a problem that it is difficult to give a fresh appearance to the appearance of the audio device in that a man-machine interface imitating a conventional audio device is used. In addition, there is a problem that the style of listening to music is standardized.
[0005]
Further, in a conventional acoustic device, acoustic characteristics are adjusted by changing a parameter prepared in advance. For this reason, even if a new application for adjusting acoustic characteristics appears in the future, there is a problem that conventional audio equipment cannot cope with the new application.
[0006]
On the other hand, in recent years, a network-connected audio device that is connected to the Internet or the like and downloads and listens to audio data from a server or the like on the Internet has appeared. In such an audio device, the above-described new application can be downloaded from a network and used. However, since such a network-connected acoustic device does not pass through an information device such as a personal computer, there is a problem that the system is often large-scale and cannot be said to be a simple device.
[0007]
Accordingly, an object of the present invention is to provide an audio device, a method of controlling the audio device, and a method of controlling the audio device, which has a possibility of renewing a style of listening to music while giving a novel design to the appearance with a simple and interactive operation method. An object of the present invention is to provide a device control device.
[0008]
[Means for Solving the Problems]
SUMMARY OF THE INVENTION In order to solve the above-described problems, the present invention provides an audio device that changes the acoustic characteristics of a digital audio signal by digital signal processing. A non-contact type device having a first communication means for performing the communication, and a non-contact type device capable of being mounted thereon, communicating with the first communication means of the mounted non-contact type device and reading out a program from the memory An audio equipment main body having a second communication means and a digital signal processing means for changing an acoustic characteristic of the input audio signal based on the setting, wherein the non-contact type device comprises a second communication means; When the digital signal processing unit is set on the digital signal processing unit, the setting of the digital signal processing unit is immediately changed based on the program read from the memory by the second communication unit. An acoustic device is characterized in that so as to.
[0009]
According to the present invention, in a control method of an audio device in which an audio characteristic is changed by digital signal processing on a digital audio signal, a first method for performing non-contact communication with a memory in which a program is stored in advance and an external device is provided. Non-contact type device having the following communication means, and the second communication for reading the program from the memory by communicating with the first communication means of the mounted non-contact type device. Means, and an audio equipment main body having digital signal processing means for changing the acoustic characteristics of the input audio signal based on the setting. After the non-contact type device is mounted on the second communication means, A step of reading the program from the memory by performing communication between the first communication means and the communication means, and the program read in the reading step. A step of changing the setting of the digital signal processing means based on the system, wherein the step of reading and the step of changing are performed immediately after the non-contact type device is mounted. This is a method for controlling an acoustic device to be controlled.
[0010]
In addition, the present invention is directed to an audio apparatus in which an acoustic characteristic is changed by digital signal processing with respect to a digital audio signal, wherein a first communication means for performing non-contact communication with a memory in which a program is stored in advance. A second communication means for communicating with the first communication means of the mounted non-contact type device and reading a program from the memory; and Digital signal processing means for changing the acoustic characteristic based on the setting, wherein when the non-contact type device is mounted on the second communication means, the program read from the memory by the second communication means immediately An audio apparatus characterized in that the setting of digital signal processing means is changed based on the following.
[0011]
Further, the present invention provides an audio equipment control method in which an audio characteristic is changed by digital signal processing with respect to a digital audio signal, wherein a memory in which a program is stored in advance and communication means for performing non-contact communication with the outside are provided. After the non-contact type device having the device is mounted, the communication step of communicating with the communication means of the non-contact type device and reading the program from the memory, based on the program read from the memory by the communication step, input based on Changing the setting of the digital signal processing means for changing the acoustic characteristics of the audio signal based on the setting, wherein the communication step and the changing step are performed immediately after the non-contact device is mounted. A method for controlling an acoustic device, wherein the method is performed.
[0012]
Further, the present invention provides an audio equipment control device for controlling the audio characteristic of an audio device in which the audio characteristic is changed by digital signal processing with respect to a digital audio signal, wherein the audio characteristic of the audio signal input to the audio device is controlled. It has a memory in which a program for performing setting for the digital signal processing means in the audio equipment to be changed based on the setting and a communication means for communicating with the outside in a non-contact manner, and is mounted on the audio equipment. A sound device control device characterized in that a program is read from a memory, and the read program is transmitted to the sound device by a communication unit.
[0013]
As described above, according to the present invention, a non-contact type device having a memory in which a program is stored in advance, a first communication unit that performs non-contact communication with the outside, and a non-contact type device can be mounted. A second communication unit that communicates with the first communication unit of the mounted non-contact type device and reads a program from a memory; and a digital signal processing unit that changes an acoustic characteristic of an input audio signal based on a setting. Immediately after the non-contact type device is mounted on the second communication means, the second communication means and the first communication means communicate with each other, and a program is read from the memory. Since the setting of the digital signal processing means is changed based on the read program, the data can be obtained simply by placing the non-contact type device on the second communication means of the audio equipment main body. Acoustic properties settings are changed digital signal processing unit is changed.
[0014]
According to the present invention, a non-contact type device having a memory in which a program is stored in advance and first communication means for performing non-contact communication with the outside can be mounted, and the mounted non-contact type device is provided. A second communication unit that communicates with the first communication unit and reads a program from a memory; and a digital signal processing unit that changes the acoustic characteristics of the input audio signal based on the setting. Since the setting of the digital signal processing means is immediately changed based on the program read from the memory by the second communication means when the device is placed on the second communication means, Just by placing, the setting of the digital signal processing means is changed and the acoustic characteristics are changed.
[0015]
Also, the present invention provides a memory in which a program for performing a setting for digital signal processing means in an audio device for changing an acoustic characteristic of an audio signal input to the audio device based on the setting is stored in advance, and a non-contact external device. And a communication means for communicating with the audio equipment. When the audio equipment is mounted on the audio equipment, the program is read from the memory and transmitted to the audio equipment by the communication means. By doing so, the digital signal processing means of the audio equipment can be set.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described. According to the present invention, by setting a device using a small IC chip at a predetermined position of an audio device, settings and programs of a digital signal processing unit provided in the audio device can be immediately changed. Adjust the acoustic characteristics of audio signals in real time. Further, at that time, it is also possible to cause a device mounted on the audio equipment to emit light of a predetermined color, and to perform an interaction based on a change in color.
[0017]
Further, the above-described device can store data for adjusting acoustic characteristics such as an equalizer customized by a user. Similarly, data provided from a third party via a recording medium such as a network or a CD-ROM (Compact Disc-Read Only Memory) can be stored in the device. By placing the device storing the data at a predetermined position of the audio device, the acoustic characteristics of the audio device are changed based on the data stored in the device.
[0018]
FIG. 1 schematically shows an external appearance of an example of an audio device 100 according to an embodiment of the present invention. The audio device 100 is a CD reproducing device that reproduces, for example, a CD (Compact Disc) and outputs reproduced sound. The button 1 is a power switch for turning on / off the power of the audio device 100. The slot 2 is a CD insertion slot into which the CD 9 is inserted, and the button 3 is an eject button for removing the CD inserted into the slot 2. The operation unit 4 is a unit for instructing start / stop of CD reproduction, volume adjustment, sound quality adjustment, and the like in the audio device 100, and operation elements corresponding to each operation are provided in a predetermined manner.
[0019]
A speaker unit 5 having an L-channel speaker 5A and an R-channel speaker 5B is provided on the front surface of the audio device 100. A display unit 8 for displaying various states of the audio device 100 is provided at the upper center of the speaker unit 5, and a remote instruction is issued to the audio device 100 at the lower center of the speaker unit 5. A receiving unit 6 is provided for receiving an infrared signal from a remote control commander (not shown).
[0020]
The device mounting section 7 is provided on the upper surface of the audio device 100. The device mounting section 7 is provided for mounting the non-contact type device 10. FIG. 2 schematically shows the appearance of the non-contact device 10 according to one embodiment of the present invention. The non-contact type device 10 has a substantially inverted conical shape, as shown in an example in FIG. The size of the non-contact type device 10 is, for example, about 2 cm to 3 cm in diameter of the inverted cone and about 2 cm to 3 cm in height. Of course, the size of the non-contact device 10 is not limited to this example.
[0021]
The non-contact device 10 is configured by, for example, laminating a disk portion 11 and an inverted conical portion 12. An electric circuit is configured in the disk unit 11. The inverted conical part 12 is formed of, for example, a translucent substance, and has a light emitting part including an LED (Light Emitting Diode) inside. The light emitted by the light emitting portion is diffused by the translucent substance, and the inverted conical portion 12 is made to shine entirely. The structure of the non-contact device 10 is not limited to this example. For example, the disk portion 11 and the inverted conical portion 12 can be formed integrally.
[0022]
The device mounting portion 7 is provided with a depression corresponding to, for example, a tip of the inverted cone of the non-contact type device 10, and the non-contact type device 10 can be placed with the tip of the inverted cone facing downward. I have. That is, the non-contact type device 10 is mounted on the device mounting portion 7 with the protruding end of the inverted cone facing downward as shown in an example in FIG. In FIG. 3, the depression corresponding to the protruding end is omitted. When the user holds the non-contact type device 10 on the device mounting portion 7 while holding the disc portion 11 side with fingers or the like and turning the protruding end portion of the inverted conical portion 12 downward, the protruding end portion of the inverted conical portion 12 The non-contact type device 10 is held so that the protruding end of the inverted cone faces downward by fitting into the recess provided in the device mounting portion 7 so as not to fall.
[0023]
Although details will be described later, the non-contact type device 10 has information for changing the acoustic characteristics of the reproduced sound in the audio device 100, and the non-contact type device 10 is stored in the device mounting section 7 of the audio device 100. By mounting, the information is read by the audio device 100, and the acoustic characteristics of the audio device 100 are changed based on the read information. The change of the acoustic characteristics in the acoustic device 100 is performed immediately after the non-contact type device 10 is mounted on the device mounting portion 7.
[0024]
FIG. 4 schematically shows a change in an example of the acoustic characteristic of the acoustic device 100 by the non-contact device 10. When the non-contact type device 10 is not mounted on the device mounting portion 7, as shown in FIG. 4A, the audio data reproduced from the CD 9 is subjected to the standard processing of the audio device 100, and the speaker 5A And 5B.
[0025]
Here, as described above, when the non-contact device 10 is placed on the audio device 100, the acoustic characteristics of the audio data reproduced from the CD 9 are changed based on the information of the non-contact device 10. You. That is, typically, as shown in FIG. 4B, the audio data reproduced from the CD 9 is output through a process based on the information of the non-contact device 10. Therefore, the sound output from the speakers 5A and 5B has sound characteristics changed compared to the sound when the non-contact device 10 of FIG. 4A is not placed.
[0026]
The change from the state shown in FIG. 4A to the state shown in FIG. 4B is made to occur in real time as the non-contact type device 10 is placed on the device placement unit 7. That is, the acoustic characteristics of the sound output from the speakers 5A and 5B by the reproduction of the CD 9 are changed at the timing when the substantially non-contact device 10 is mounted on the device mounting portion 7 during the reproduction of the CD 9. Therefore, the user can recognize a change in acoustic characteristics due to placing the non-contact type device 10 on the device placing section 7 substantially in real time.
[0027]
The shape of the inverted cone of the non-contact device 10 is a metaphor of a record needle used in an analog record player. As described above, by placing the non-contact device 10 on the device mounting portion 7, the acoustic characteristics of the sound being reproduced are changed corresponding to the non-contact device 10 on which the device is placed. Therefore, when the user himself places the non-contact type device 10 having the shape of an inverted cone on the device placement part 7, the user plays back the record by, for example, lowering the record needle by himself on an analog record player. In another example, it is possible to enjoy an interactive feeling that is not present in conventional digital devices, such as reproducing a sound, and changing a reproduced sound quality by replacing a cartridge portion of an analog record player. Such interactive sensations between the user and the audio device are considered to be important, especially when dealing with extremely sensory objects such as music.
[0028]
Next, the above-described non-contact type device 10 and acoustic device 100 will be described more specifically. FIG. 5 is a cross-sectional view of an example showing the non-contact device 10 and the device mounting section 7 in a cross-sectional direction. The inverted conical portion 12 of the non-contact type device 10 is formed of, for example, a translucent resin, and has a hole 13 for a light emitting unit such as an LED. When the light emitting portion embedded in the hole 13 is turned on, the whole of the translucent inverted conical portion 12 is made to dim due to diffusion of light.
[0029]
In addition, the protruding end of the inverted conical portion 12 may be formed slightly flat as shown in an example in FIG. Even in this case, the device mounting portion 7 has a depression corresponding to the slightly flattened tip of the inverted conical portion 12, as in the example of FIG. In this shape, the non-contact type device 10 is more securely held, which is preferable.
[0030]
On the acoustic device 100 side, a sensor unit 20 is provided at a position corresponding to the disk unit 11 of the non-contact type device 10 when the non-contact type device 10 is mounted on the device mounting unit 7. The sensor unit 20 determines whether or not the non-contact type device 10 is mounted on the device mounting unit 7 by communicating with, for example, a circuit unit configured inside the disk unit 11 of the non-contact type device 10. . When the non-contact device 10 is mounted on the device mounting unit 7, the sensor unit 20 and the circuit unit inside the disk unit 11 communicate with each other in a non-contact manner, and are stored in the disk unit 11. The read information is read by the sensor unit 20. The read information is supplied from the sensor unit 20 to a circuit inside the audio device 100.
[0031]
FIG. 6 shows an example circuit configured in the non-contact device 10. The circuit shown in FIG. 6 is configured, for example, in the disk unit 11. The non-contact type device 10 includes an IC (Integrated Circuit) unit 30, an antenna 31, an LED 32 serving as the light emitting unit, and a power supply unit 33. The power supply unit 33 can be incorporated in the IC unit 30. The antenna 31 is configured to be able to transmit and receive signals and generate power by electromagnetic induction. As an example, as shown in FIG. 7, for example, it is helically embedded in the disk portion 11. In FIG. 7, the power supply unit 33 is omitted.
[0032]
An antenna 31 is connected to the IC unit 30 and the power supply unit 33. The power supply unit 33 rectifies and smoothes the output received by the antenna 31 and converts the output to a constant voltage, and supplies it to the IC unit 30 as a power supply voltage.
[0033]
On the other hand, the IC unit 30 has a CPU (Central Processing Unit), a memory, and an RF function. The reception output supplied from the antenna 31 is first supplied to the RF unit in the IC unit 30, and a signal obtained by modulating predetermined data or a command at the time of transmission is demodulated. The demodulated data and commands are supplied to the CPU unit. On the other hand, the memory of the IC unit 30 has a storage capacity of several to several tens of kilobytes, and stores programs and data for the DSP unit described later in advance. The CPU reads these programs and data from the memory based on the supplied data and commands. The read program or data is supplied to the RF unit, modulated, converted into a transmission signal, and transmitted from the antenna 31.
[0034]
FIG. 8 schematically illustrates a configuration of an example of the audio device 100. The reproducing unit 40 includes an optical pickup, a CD driving system including a spindle motor and a servo circuit, a waveform shaping circuit, an EFM (Eight to Fourteen Modulation) demodulating circuit, a signal processing circuit, and an error caused by a CIRC (Cross Interleaved Reed-Solomon Code). It is composed of a detection and correction circuit and the like, and reproduces the CD 9 and outputs a digital audio signal.
[0035]
The digital audio signal output from the reproduction unit 40 is supplied to a DSP (Digital Signal Processor) unit 41. The DSP unit 41 performs digital signal processing on a digital audio signal based on a program or data stored in a random access memory (RAM) 42. By rewriting the contents of the RAM 42, a different digital signal is used. The processing can be executed. By the digital signal processing by the DSP unit 41, the acoustic characteristics of the digital audio signal output from the reproduction unit 40 are changed. Although details will be described later, for example, equalization (change of frequency characteristics), spatial processing, and the like can be realized by digital signal processing by the DSP unit 41.
[0036]
The digital audio signal output from the DSP unit 41 is converted into an analog audio signal by the D / A converter 43. The analog audio signal output from the D / A converter 43 is amplified in voltage and power by the amplifier 44 and supplied to the speakers 5A and 5B to be output as a stereo sound.
[0037]
Although not shown, the entire operation of the acoustic device 100 is controlled by a system controller (not shown). The system controller includes, for example, a CPU, a RAM, and a ROM, and communicates with the above-described playback unit 40, DSP unit 41, D / A converter 43, and sensor unit 20 to control each unit. For example, a control signal corresponding to the operation on the operation unit 4 described above is supplied from the operation unit 4 to the system controller. The system controller controls each unit of the audio device 100 based on the control signal. Various operations corresponding to operations on the power button 1 and the eject button 3 are similarly controlled by the system controller. In the system controller, a display control signal corresponding to the state of each unit of the audio device 100 is generated and supplied to the display unit 8. A predetermined display is made on the display unit 8 based on the display control signal.
[0038]
On the other hand, when the sensor unit 20 detects that the non-contact device 10 is mounted on the device mounting unit 7, communication is performed between the sensor unit 20 and the non-contact device 10 as described above. The information stored in the memory in the IC unit 30 of the non-contact type device 10, that is, the program or data for the DSP unit 41 is read. The read programs and data are supplied from the sensor unit 20 to the RAM 42 and written into the RAM 42. If the writing is performed normally, the fact is transmitted from the sensor unit 20 to the non-contact type device 10, and the success of the communication is notified. If the writing is not performed normally, the sensor unit 20 requests the non-contact device 10 to communicate again.
[0039]
Therefore, in the acoustic device 100 according to the embodiment of the present invention, the content of the acoustic processing by the DSP unit 41 is automatically changed by placing the non-contact type device 10 on the device placing unit 7 of the acoustic device 100. Thus, the reproduced sound can be changed.
[0040]
Actually, communication between the sensor unit 20 and the non-contact type device 10 and writing of programs and data to the RAM 42 are performed under the control of the system controller.
[0041]
In the above description, the digital signal processing on the digital audio signal output from the reproduction unit 40 is performed using the DSP, but this is not limited to this example. Digital signal processing for the digital audio signal can be performed using, for example, a CPU. In the digital signal processing using the CPU, similarly to the case of the DSP, a program for performing the digital signal processing is provided by the non-contact device 10 and stored in the RAM 42 via the sensor unit 20 and read from the RAM 42 to the CPU. This is done by letting The CPU may be provided exclusively for digital signal processing, or may also be used as a system controller if the capability of the CPU is sufficiently high.
[0042]
An example of a communication operation performed between the sensor unit 20 and the non-contact type device 10 will be described. The sensor unit 20 has a structure sufficient to generate sufficient electric power to drive the IC unit 30 by electromagnetic induction in the antenna 31 in the non-contact type device 10. For example, the sensor unit 20 has an antenna (not shown) similar to the antenna 31 included in the non-contact type device 10, and supplies a predetermined high-frequency power to this antenna. When the non-contact device 10 reaches a certain distance from the sensor unit 20, power is generated by electromagnetic induction in the antenna 31 according to the high-frequency power supplied to the antenna, and the IC unit 30 is operated by the power. You.
[0043]
Here, in the sensor unit 20, communication between the non-contact type device 10 in which the IC unit 30 operates and the sensor unit 20 is performed by modulating a predetermined command or data to the high-frequency power supplied to the antenna. Can be started. For example, the sensor unit 20 includes a modulation unit (not shown) that performs predetermined modulation on digital data to generate a high-frequency signal, modulates predetermined commands and data based on an instruction from a system controller, and supplies the modulated commands and data to the antenna. .
[0044]
The power of the high-frequency signal supplied to the antenna is sufficient for driving the IC unit 30 by electromagnetic induction by the antenna 31 when the distance between the antenna 31 and the sensor unit 20 of the non-contact type device 10 is within a certain distance, for example. The power is sufficient to generate power.
[0045]
In the non-contact type device 10, the antenna 31 is electromagnetically induced by the high-frequency power supplied to the antenna of the sensor unit 20, and the antenna 31 generates power. This power output of the antenna 31 is supplied to the power supply unit 33, and a power supply voltage for driving the IC unit 30 is obtained. When the IC unit 30 is operated by the power supply voltage, a signal received by the antenna 31 is demodulated by the RF unit, and commands and data are extracted. If the reception is successful, the fact is transmitted to the sensor unit 20. As a result of such an exchange between the sensor unit 20 and the non-contact type device 10, communication between the sensor unit 20 and the non-contact type device 10 is established. When communication is established, a voltage is supplied to the LED 32 by the IC unit 30, and the LED 32 emits light. Thereby, the user can know the success of the communication.
[0046]
When the communication is established, a command indicating an instruction to read a program stored in the memory of the IC unit 30 is transmitted from the sensor unit 20 to the non-contact device 10 based on the control of the system controller. You. This command is supplied to the CPU of the IC unit 30, and the information stored in the memory in the IC unit 30 is read under the control of the CPU. The read information is modulated by the RF unit and transmitted from the antenna 31. A transmitting antenna may be provided separately from the antenna 31.
[0047]
The transmission signal from the non-contact type device 10 is received by the sensor unit 20, demodulated to extract information, supplied to the RAM 42 of the DSP unit 41, and written into the RAM 42. The contents of the signal processing in the DSP unit 41 are changed by rewriting the contents of the RAM 42.
[0048]
The reading of the information stored in the memory of the non-contact device 10 and the transmission of the read information to the sensor unit 20 are performed by completely mounting the non-contact device 10 on the device mounting unit 7. It is preferable that the operation be started immediately after the operation, because the operation does not cause any unnatural feeling. That is, immediately after the user reliably recognizes that the non-contact type device 10 is mounted on the device mounting portion 7 through, for example, tactile sensation, a change in the acoustic characteristic according to the memory content of the non-contact type device 10 is performed. Is caused. By doing so, the user can intuitively associate the placement of the non-contact type device 10 with the change in the acoustic characteristics.
[0049]
For example, after detecting that the non-contact type device 10 is mounted on the device mounting portion 7, transmission of the above-described command and data from the sensor portion 20 to the non-contact type device 10 is started. The detection of the placement of the non-contact type device 10 on the device mounting portion 7 is performed, for example, by providing the device mounting portion 7 with a mechanism for detecting the weight of the non-contact type device 10. The placement of the non-contact type device 10 may be detected using electrical contact. It is also possible to detect by measuring the electric field strength using the antenna of the sensor unit 20.
[0050]
Further, when the communication between the non-contact type device 10 and the sensor unit 20 is successful, the LED 33 in the non-contact type device 10 is mounted after the non-contact type device 10 is mounted on the device mounting unit 7 until it is removed. Is controlled to continue emitting light. For example, in the sensor unit 20, high-frequency power is continuously supplied to the antenna in the sensor unit 20 so that the antenna 31 of the non-contact type device 10 can generate enough power to cause the LED 33 to emit light by electromagnetic induction. .
[0051]
Next, the sound processing performed by the DSP unit 41 will be schematically described. Representative examples of sound processing that can be configured by the DSP unit 41 include an equalizer and spatial processing. The equalizer changes the frequency characteristic of the audio signal, divides the frequency band, controls the level of each of the divided bands, and sets one or more center frequencies, and sets the center frequency to the set center frequency. On the other hand, it is roughly classified into a parametric equalizer for setting a level and a Q. It is possible to correct the influence on the sound due to the spatial state such as the wall surface of the listening room, and to make a positive sound structure such as emphasizing the bass range. You can also set each of the left and right stereo channels.
[0052]
Spatial processing adds spatial information to an audio signal, and is realized by reverberation processing, phase control, and the like. It is possible to add a sense of depth to the reproduced sound, enhance a sense of stereo, correct the effect on the sound due to the spatial state of the listening room, and the like. It is also possible to apply spatial processing to the audio signal so that the sound of a specific hall is reproduced in the listening room.
[0053]
Needless to say, by combining the above-described spatial processing with the equalizer, it is possible to perform more various and higher-quality processing. Further, the sound processing by the DSP unit 41 described above is an example, and the present invention is not limited to these examples. For example, tone control such as general volume control, bass, and treble can be performed by the DSP unit 41. The dynamics such as the compression and expansion of the level of the audio signal can be controlled by the DSP unit 41. Further, for example, it is also possible to add more special effects to the audio signal.
[0054]
A program for instructing the DSP unit 41 to perform the above-described acoustic processing is stored in the memory of the non-contact device 10 in advance. As described above, the memory of the non-contact device 10 has a storage capacity of several to several tens of kilometers, so that the program data for the DSP unit 41 can be sufficiently stored. The user selects one of the plurality of non-contact devices 10 each storing a different program and places the same on the device mounting unit 7 so that the program stored in the non-contact device 10 is changed as described above. As a result, the content of the signal processing in the DSP unit 41 is changed, and desired audio processing can be obtained in the audio device 100.
[0055]
For example, when the audio equipment 100 is installed in a living room, the non-contact type device 10 that normally performs the user's favorite sound processing is used. The non-contact device 10 in which a program for instructing the suppressed acoustic processing is stored is used. Acoustic characteristics can be changed immediately from a normal listening environment to a guest environment.
[0056]
Further, for example, a non-contact type device 10 for instructing sound processing corresponding to a music genre such as jazz, classical music, and pops can be prepared for each genre. By selecting and using the non-contact device 10 that performs sound processing corresponding to the genre of the music to be listened, it is possible to enjoy the feeling of listening to music while exchanging cartridges with an analog record player.
[0057]
Furthermore, if the emission colors of the LEDs 33 of the non-contact devices 10 storing different programs are made different, the difference in acoustic characteristics due to the difference of the non-contact devices 10 can be visually recognized, which is more effective. . By using a color filter or using a combination of LEDs of different emission colors, more diverse emission colors can be obtained.
[0058]
When the non-contact device 10 is not mounted on the device mounting section 7, the audio device 100 reproduces an audio signal with default acoustic characteristics. When the non-contact device 10 is removed from the device mounting portion 7, the acoustic characteristics of the reproduced sound in the audio device 100 are returned to the default state. For example, when the non-contact type device 10 is removed from the device mounting section 7, the contents stored in the RAM 42 are initialized under the control of the system controller, and the processing of the DSP section 41 is returned to the default.
[0059]
The program of the DSP unit 41 stored in the non-contact type device 10 and the usage example of the non-contact type device 10 corresponding thereto are not limited to the above-described example, and can be variously considered. A program that simulates the acoustic characteristics of a well-known hall can be stored in the memory of the non-contact device 10, or the frequency characteristics may be programmed with emphasis. Furthermore, within the range permitted by the specifications of the DSP unit 41, a program for instructing a completely new sound processing can be stored in the non-contact device 10.
[0060]
Furthermore, by making the memory of the non-contact device 10 rewritable, the user himself can create a program for instructing the DSP unit 41 to perform acoustic processing and store the program in the memory of the non-contact device 10. . For example, a program can be created and stored in the memory of the non-contact type device 10 by operating the operation unit 4 in a state where the non-contact type device 10 is mounted on the device mounting portion 7. . However, the present invention is not limited to this. For example, an interface capable of communicating between the personal computer and the non-contact device 10 may be provided, and a program created on the personal computer may be stored in the memory of the non-contact device 10. In this case, for example, a program provided from the outside by a communication medium such as a recording medium such as a flexible disk or a CD-ROM (Compact Disc-Read Only Memory) or the Internet can be stored in the memory of the non-contact device 10.
[0061]
In the above description, the program stored in the memory of the non-contact type device 10 is written in the RAM 42 which is a part of the DSP unit 41, but this is not limited to this example. For example, the memory of the non-contact device 10 may be configured to be a part of the DSP unit 41.
[0062]
Further, in the above description, the non-contact type device 10 is described as being provided directly to the audio equipment 100, but this is not limited to this example. For example, the device mounting section and the sensor section 20 may be provided for a remote control commander (not shown) for remotely controlling the acoustic device 100 using an infrared signal or the like. In this case, by performing a predetermined operation on the remote control commander on which the non-contact type device 10 is mounted, the program stored in the memory of the non-contact type device 10 is transmitted to the audio device 100 via the remote control commander. Sent. On the audio device 100 side, the receiving unit 6 can receive this signal and rewrite the contents of the RAM 42.
[0063]
【The invention's effect】
As described above, in the present invention, since the program for changing the acoustic characteristics is stored in the non-contact type device, complicated settings for changing the acoustic characteristics can be easily performed only by placing the non-contact type device. There is an effect that can be changed to.
[0064]
Further, by replacing the non-contact type device, there is an effect that different acoustic characteristics can be easily obtained with the same device.
[0065]
Furthermore, since a program for changing the acoustic characteristics is stored in the non-contact type device, it is possible to add a new setting for the change in the acoustic characteristics only by adding the non-contact type device in which the corresponding program is stored. There is an effect that it can be performed. Similarly, when a new parameter for the change in the acoustic characteristic is devised, the change in the acoustic characteristic based on the new parameter can be obtained by simply adding the non-contact type device in which the setting based on the devised parameter is stored. Obtainable.
[0066]
Also, since the acoustic characteristics of the audio equipment are changed by placing an inverted conical non-contact device on the audio equipment, the interface and appearance of the audio equipment can be renewed from the conventional one. There is.
[0067]
Furthermore, since the user changes the acoustic characteristics by the act of placing the entity of the non-contact type device on the audio equipment by himself, there is an effect that the user can obtain a tactile sensation when listening to music.
[Brief description of the drawings]
FIG. 1 is a schematic diagram schematically showing an external appearance of an example of an audio device according to an embodiment of the present invention.
FIG. 2 is a schematic diagram schematically showing an appearance of a non-contact device according to one embodiment of the present invention.
FIG. 3 is a schematic diagram for explaining a method of mounting a non-contact type device on a device mounting portion.
FIG. 4 is a schematic diagram schematically showing a change in an example of acoustic characteristics of an acoustic device by a non-contact device.
FIG. 5 is a cross-sectional view of an example showing a non-contact type device and a device mounting portion from a cross-sectional direction.
FIG. 6 is a block diagram illustrating an example circuit configured in a non-contact device.
FIG. 7 is a schematic diagram illustrating a structure of an example of an antenna provided in a non-contact type device.
FIG. 8 is a block diagram schematically illustrating a configuration of an example of an audio device.
[Explanation of symbols]
7: Device mounting part, 10: Non-contact type device, 11: Disk part, 12: Inverted conical part, 20: Sensor part, 30: IC part, 31 ... -Antenna, 32-LED, 40-Reproducing unit, 41-DSP unit, 42-RAM, 43-D / A converter, 44-Amplifier, 100-Sound machine

Claims (21)

For audio equipment that changes the acoustic characteristics of digital audio signals by digital signal processing,
A memory in which the program is stored in advance;
A non-contact type device having first communication means for performing non-contact communication with the outside;
A second communication unit capable of mounting the non-contact type device, communicating with the first communication unit of the mounted non-contact type device, and reading the program from the memory;
Digital audio signal processing means for changing the acoustic characteristics of the input audio signal based on the settings, and
When the non-contact type device is placed on the second communication means, the audio equipment body immediately executes the digital signal processing based on the program read from the memory by the second communication means. An acoustic device wherein the setting of the means is changed. The audio device according to claim 1,
When the non-contact type device is mounted on the second communication means during processing of the audio signal by the digital signal processing means, the acoustic characteristic main body corresponds to the timing of the mounting. The setting of the digital signal processing means is changed based on the program read and read from the memory by the second communication means so as to change the acoustic characteristic of the signal according to the change of the setting. An acoustic device characterized by performing. The audio device according to claim 1,
An acoustic device, wherein the non-contact device has a substantially inverted conical shape. The audio device according to claim 1,
An acoustic device, wherein the non-contact device communicates with the communication means using electromagnetic waves. The audio device according to claim 1,
An acoustic device, wherein the non-contact device has a light emitting means, and causes the light emitting means to emit light when communication with the communication means is successful. The audio device according to claim 1,
An acoustic device wherein the non-contact device supplies its own power using electromagnetic induction. In a control method of an audio device which changes an acoustic characteristic by digital signal processing with respect to a digital audio signal,
A memory in which the program is stored in advance;
A non-contact type device having first communication means for performing non-contact communication with the outside;
A second communication unit capable of mounting the non-contact type device, communicating with the first communication unit of the mounted non-contact type device, and reading the program from the memory;
Digital audio signal processing means for changing the acoustic characteristics of the input audio signal based on the settings, and
After the non-contact type device is mounted on the second communication means, a step of reading the program from the memory by communicating with the second communication means and the first communication means,
A step of changing the setting of the digital signal processing means based on the program read in the reading step,
The method of controlling an audio device, wherein the reading step and the changing step are performed immediately after the non-contact device is placed above. The control method for an audio device according to claim 7,
When the non-contact type device is mounted on the second communication means during the processing of the audio signal by the digital signal processing means, the acoustic characteristic of the audio signal is changed in accordance with the mounting timing. The setting of the digital signal processing means is changed based on the program read and read from the memory by the second communication means in the reading step so as to be changed in accordance with the change of the setting. A method for controlling an acoustic device, wherein the method is performed in a changing step. For audio equipment that changes the acoustic characteristics of digital audio signals by digital signal processing,
A non-contact type device having a memory in which a program is stored in advance and first communication means for performing non-contact communication with the outside can be mounted, and the first non-contact type of the mounted non-contact type device can be mounted. Second communication means for communicating with the communication means and reading the program from the memory;
Digital signal processing means for changing the acoustic characteristics of the input audio signal based on the setting,
Immediately after the non-contact device is mounted on the second communication means, the setting of the digital signal processing means is changed based on the program read from the memory by the second communication means. An audio device characterized in that: The acoustic device according to claim 9,
When the non-contact type device is mounted on the second communication means during the processing of the audio signal by the digital signal processing means, the acoustic characteristic of the audio signal is changed in accordance with the mounting timing. The setting of the digital signal processing means is changed based on the program read and read from the memory by the second communication means so as to be changed according to the change of the setting. Characteristic acoustic equipment. The acoustic device according to claim 9,
An acoustic device, wherein the non-contact device has a substantially inverted conical shape. The acoustic device according to claim 9,
An acoustic device, wherein the non-contact device communicates with the communication means using electromagnetic waves. The acoustic device according to claim 9,
An acoustic device, wherein the non-contact device has a light emitting means, and causes the light emitting means to emit light when communication with the communication means is successful. The acoustic device according to claim 9,
An acoustic device wherein the non-contact device supplies its own power using electromagnetic induction. In a control method of an audio device which changes an acoustic characteristic by digital signal processing with respect to a digital audio signal,
After a non-contact type device having a memory in which a program is stored in advance and a communication unit that performs non-contact communication with the outside is mounted, the non-contact type device communicates with the communication unit of the non-contact type device, and the Communication steps for reading the program;
Based on the program read from the memory by the communication step, a step of changing the setting of the digital signal processing means for changing the acoustic characteristics of the input audio signal based on the setting,
The method of controlling an acoustic device, wherein the communication step and the change step are performed immediately after the non-contact type device is placed as described above. The control method for an audio device according to claim 15,
When the non-contact type device is placed during the processing of the audio signal by the digital signal processing means, the acoustic characteristic of the audio signal is changed in accordance with the setting according to the timing of the placement. The setting of the digital signal processing means is changed in the changing step based on the program read and read from the memory in the communication step so as to change the setting. A control method for audio equipment. For an audio equipment control device for controlling the audio characteristics of an audio device that changes its acoustic characteristics by digital signal processing with respect to a digital audio signal,
A memory in which a program for performing the setting for the digital signal processing means in the audio device that changes the acoustic characteristics of the audio signal input to the audio device based on the setting is stored in advance,
Communication means for communicating with the outside without contact,
The sound is characterized in that the program is read from the memory when placed on the audio device, and the read program is transmitted to the audio device by the communication means. Equipment control device. The audio equipment control device according to claim 17,
An audio equipment control device having a substantially inverted conical shape. The audio equipment control device according to claim 17,
An acoustic equipment control device according to claim 1, wherein said communication means performs communication using electromagnetic waves. The audio equipment control device according to claim 17,
An audio equipment control device, further comprising a light emitting unit, wherein the light emitting unit emits light when communication by the communication unit is successful. The audio equipment control device according to claim 17,
An audio equipment control device characterized in that it supplies its own power using electromagnetic induction.

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