WO2014196399A1 - 入力デバイス及び送信方法、ホストデバイス及び受信方法、並びに、信号処理システム及び送受信方法 - Google Patents
入力デバイス及び送信方法、ホストデバイス及び受信方法、並びに、信号処理システム及び送受信方法 Download PDFInfo
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- WO2014196399A1 WO2014196399A1 PCT/JP2014/063825 JP2014063825W WO2014196399A1 WO 2014196399 A1 WO2014196399 A1 WO 2014196399A1 JP 2014063825 W JP2014063825 W JP 2014063825W WO 2014196399 A1 WO2014196399 A1 WO 2014196399A1
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- plug
- jack
- multiplexed data
- input device
- signal
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R1/00—Details of transducers, loudspeakers or microphones
- H04R1/10—Earpieces; Attachments therefor ; Earphones; Monophonic headphones
- H04R1/1083—Reduction of ambient noise
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R1/00—Details of transducers, loudspeakers or microphones
- H04R1/06—Arranging circuit leads; Relieving strain on circuit leads
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R3/00—Circuits for transducers, loudspeakers or microphones
- H04R3/005—Circuits for transducers, loudspeakers or microphones for combining the signals of two or more microphones
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R2201/00—Details of transducers, loudspeakers or microphones covered by H04R1/00 but not provided for in any of its subgroups
- H04R2201/10—Details of earpieces, attachments therefor, earphones or monophonic headphones covered by H04R1/10 but not provided for in any of its subgroups
- H04R2201/107—Monophonic and stereophonic headphones with microphone for two-way hands free communication
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R2410/00—Microphones
- H04R2410/05—Noise reduction with a separate noise microphone
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R2420/00—Details of connection covered by H04R, not provided for in its groups
- H04R2420/01—Input selection or mixing for amplifiers or loudspeakers
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R2420/00—Details of connection covered by H04R, not provided for in its groups
- H04R2420/09—Applications of special connectors, e.g. USB, XLR, in loudspeakers, microphones or headphones
Definitions
- the present technology relates to an input device and a transmission method, a host device and a reception method, and a signal processing system and a transmission and reception method, and in particular, a plurality of electrical signals from, for example, a plug device having a plug to a jack device having a jack.
- the present invention relates to an input device and a transmission method, a host device and a reception method, and a signal processing system and a transmission / reception method that can easily transmit and receive multiplexed multiplexed data.
- the present technology has been made in view of such a situation, and enables easy transmission / reception of multiplexed data obtained by multiplexing a plurality of electrical signals from a plug device to a jack device. It is.
- the input device of the present technology includes a plug inserted into the jack of a jack device having a jack, a plurality of conversion units that convert physical quantities into electric signals, and the jack device that outputs the electric power output from the plurality of conversion units.
- An input device including a transmission processing unit.
- the transmission method of the present technology includes: an input device including a plug inserted into the jack of a jack device having a jack; and a plurality of conversion units that convert a physical quantity into an electrical signal.
- the jack device includes the plurality of conversion units. Detecting whether or not the device is a compatible device capable of handling multiplexed data obtained by multiplexing the electrical signal output by the device, and when the jack device is the compatible device, the multiplexed data is transmitted via the plug. And transmitting the input device.
- the jack device a compatible device that can handle multiplexed data obtained by multiplexing the electrical signals output from the plurality of conversion units? Whether it is detected.
- the jack device is the corresponding device, the multiplexed data is transmitted via the plug.
- the host device of the present technology is a multiplexing device in which the electrical signal output from the jack into which the plug of the plug device having a plug is inserted and the plug device outputs a plurality of conversion units that convert physical quantities into electrical signals is multiplexed.
- a host device having a jack into which the plug of the plug device having a plug is inserted the plug device multiplexes the electrical signal output from a plurality of conversion units that convert physical quantities into electrical signals. If the plug device is the corresponding device, the multiplexed data transmitted from the plug device, which is the corresponding device, is detected.
- the host device receiving method includes the step of receiving via the jack.
- the plug device can handle multiplexed data obtained by multiplexing the electrical signals output from a plurality of conversion units that convert physical quantities into electrical signals. It is detected whether it is a corresponding device capable. When the plug device is the corresponding device, the multiplexed data transmitted from the plug device which is the corresponding device is received via the jack.
- the signal processing system of the present technology includes a plug inserted into the jack of a jack device having a jack, a plurality of conversion units that convert a physical quantity into an electrical signal, and the jack device that outputs the plurality of conversion units.
- a detection unit that detects whether the device is a compatible device capable of handling multiplexed data obtained by multiplexing electrical signals; and when the jack device is the compatible device, the multiplexed data is transmitted via the plug.
- An input device having a transmission processing unit for transmitting; a jack into which the plug of the plug device having a plug is inserted; another detection unit for detecting whether the plug device is the corresponding device; and the plug When the device is the corresponding device, it is transmitted from the plug device that is the corresponding device.
- the transmission / reception method of the present technology includes: an input device including a plug inserted into the jack of a jack device having a jack; and a plurality of conversion units that convert a physical quantity into an electric signal; Detecting whether or not the device is a compatible device capable of handling multiplexed data obtained by multiplexing the electrical signal output by the device, and when the jack device is the compatible device, the multiplexed data is transmitted via the plug. And a host device having a jack into which the plug of the plug device having a plug is inserted detects whether the plug device is the corresponding device, and the plug device is the corresponding device. The plug device that is the corresponding device The duplexed data, a transmitting and receiving method comprising the steps of: receiving via said jack.
- the jack device can handle multiplexed data obtained by multiplexing the electrical signals output from the plurality of conversion units. Whether the device is a compatible device is detected, and if the jack device is the compatible device, the multiplexed data is transmitted through the plug. Further, in the host device, it is detected whether or not the plug device is the corresponding device, and when the plug device is the corresponding device, the multiplexing transmitted from the plug device that is the corresponding device. Data is received via the jack.
- the input device and the host device may be independent devices or may be a part of one device.
- FIG. 2 is a block diagram illustrating a first detailed configuration example of a host device 10 and an input device 20.
- FIG. 4 is a flowchart for explaining processing of a host device 10 and an input device 20.
- 3 is a block diagram illustrating a second detailed configuration example of a host device 10 and an input device 20.
- FIG. 5 is a block diagram illustrating a third detailed configuration example of the host device 10 and the input device 20.
- FIG. 10 is a block diagram illustrating a fourth detailed configuration example of the host device 10 and the input device 20.
- FIG. 10 is a block diagram illustrating a fifth detailed configuration example of the host device 10 and the input device 20.
- FIG. 10 is a block diagram illustrating a sixth detailed configuration example of the host device 10 and the input device 20.
- FIG. 4 is a flowchart for explaining processing of a host device 10 and an input device 20.
- 10 is a block diagram illustrating a seventh detailed configuration example of the host device 10 and the input device 20.
- FIG. 3 is a timing chart illustrating an example of signals exchanged between a host device 10 and an input device 20.
- 3 is a timing chart illustrating an example of signals exchanged between a host device 10 and an input device 20.
- 4 is a timing chart illustrating an example of a signal as a command transmitted from the host device 10 to the input device 20. It is a block diagram which shows the structural example of FB system NC system which performs FB system NC.
- FIG. 1 is a perspective view illustrating an external configuration example of an application system to which a host device 10 and an input device 20 are applied. It is a block diagram which shows the electrical structural example of an application system. 6 is a diagram showing an example of device information stored in a nonvolatile memory 85.
- FIG. 3 is a circuit diagram illustrating a configuration example of a switch unit 401.
- FIG. It is a circuit diagram which shows the structural example of the switch part 401 at the time of providing a protective diode.
- 3 is a circuit diagram illustrating a configuration example of a switch unit 411.
- FIG. 18 is a block diagram illustrating a configuration example of an embodiment of a computer to which the present technology is applied.
- FIG. 1 shows a signal processing system to which the present technology is applied (a system is a logical collection of a plurality of devices, regardless of whether or not each component device is in the same housing). It is a block diagram which shows the structural example of one embodiment.
- the signal processing system includes a host device 10 and an input device 20.
- the host device 10 includes a signal processing block 11, an analog acoustic interface 12, a multiplexed data interface 13, a jack 14, and a clock generation unit 15.
- the host device 10 is a jack device having a jack.
- the host device 10 is a plug device having the plug, for example, a plurality of digital signals (electrical signals) transmitted from the input device 20.
- the multiplexed data obtained by multiplexing the signal) is received by the multiplexed data interface 13 via the jack 14.
- various signal processing is performed in the signal processing block 11 using the digital signal included in the multiplexed data received by the multiplexed data interface 13.
- a mobile device capable of signal processing such as a mobile phone, a smartphone, a portable music player, a digital camera, or a notebook PC (Personal Computer) can be used.
- a notebook PC Personal Computer
- any device capable of signal processing such as a tablet terminal, a stationary PC, and a TV (television receiver) can be adopted.
- the signal processing block 11 includes, for example, an MPU (Micro-Processing Unit) composed of a processor such as a CPU (Central Processing Unit) or a DSP (Digital Signal Processor), and is supplied from the multiplexed data interface 13. Various signal processing is performed using a digital signal included in the data and an analog signal supplied from the analog acoustic interface 12.
- MPU Micro-Processing Unit
- CPU Central Processing Unit
- DSP Digital Signal Processor
- the signal processing block 11 supplies an analog sound signal obtained by signal processing or the like to the analog sound interface 12 or a command to the input device 20 to the multiplexed data interface 13 as necessary. Supply and other control of the entire host device 10 are performed.
- the analog acoustic interface 12 is an interface for transmitting and receiving an analog acoustic signal via the jack 14, and the analog acoustic signal supplied from the signal processing block 11 is plugged into the jack 14 with a plug inserted into the jack 14 ( For example, it is transmitted to the input device 20).
- the analog acoustic interface 12 receives an analog signal (analog acoustic signal or the like) transmitted from a plug device in which a plug is inserted into the jack 14 and supplies the analog signal to the signal processing block 11.
- an analog signal analog acoustic signal or the like
- the multiplexed data interface 13 is an interface for transmitting / receiving digital multiplexed data via the jack 14.
- the multiplexed data interface 13 receives multiplexed data transmitted from a plug device having a plug inserted into the jack 14, and receives signals. Supply to processing block 11.
- the multiplexed data interface 13 transmits a signal (command or the like) supplied from the signal processing block 11 to a plug device in which a plug is inserted into the jack 14.
- the plug of the plug device is inserted into the jack 14.
- the clock generation unit 15 generates a predetermined clock and supplies it to a necessary block of the host device 10.
- the host device 10 operates in synchronization with the clock generated by the clock generation unit 15.
- the analog acoustic interface 12 is not essential.
- the input device 20 includes an analog acoustic interface 21, a multiplexed data interface 22, and a plug 23.
- the input device 20 is a plug device having a plug.
- the input device 20 is a jack device having the jack.
- the host device 10 sends multiplexed data to the multiplexed data interface 13. Then, the data is transmitted through the plug 23.
- the input device 20 functions as a device for inputting (supplying) multiplexed data to the host device 10.
- a device having a plurality of conversion units (transducers) that convert a physical quantity into an electric signal such as a headset having a plurality of microphones, can be employed.
- the analog acoustic interface 21 is an interface for transmitting and receiving an analog acoustic signal via the plug 23. For example, an analog acoustic signal obtained by a microphone (not shown in FIG. 1) is transmitted to the plug 23. Send to jack device with jack inserted.
- the analog sound interface 21 receives an analog sound signal transmitted from the jack device in which the plug 23 is inserted into the jack, and outputs (sounds) sound corresponding to the sound signal.
- the multiplexed data interface 22 is an interface for transmitting and receiving digital multiplexed data via the plug 23.
- analog audio signals obtained by a plurality of microphones are converted into AD.
- the multiplexed data obtained by multiplexing the digital data obtained by (Analog ⁇ ⁇ ⁇ ⁇ Digital) conversion is transmitted to the jack device in which the plug 23 is inserted into the jack.
- the multiplexed data interface 22 receives a signal (command or the like) transmitted from a jack device (for example, the host device 10) in which the plug 23 is inserted into the jack, and performs a predetermined process.
- a jack device for example, the host device 10.
- the plug 23 is inserted into a jack included in the jack device.
- the analog acoustic interface 21 is not essential.
- the host device 10 since the host device 10 has the multiplexed data interface 13, it can handle digital multiplexed data as will be described later, and the input device 20 has the multiplexed data interface 22, which will be described later. As described above, digital multiplexed data can be handled.
- the host device 10 and the input device 20 are both compatible devices.
- a smartphone having a function of a device for processing an acoustic signal such as a music player or a telephone is adopted as the host device 10 and connected to the host device 10 as a smartphone as the input device 20.
- the host device 10 and the input device 20 A detailed configuration example of the host device 10 and the input device 20 will be described.
- FIG. 2 is a block diagram illustrating a first detailed configuration example of the host device 10 and the input device 20.
- a 4-pole jack and a plug are adopted as the jack 14 and the plug 23, respectively.
- the jack 14 has two (stereo) acoustic signal terminals TJ1 and TJ2, one microphone terminal TJ3, and one ground terminal TJ4, and the plug 23 also has two acoustic signal terminals TP1 and TP2,1. There are two microphone terminals TP3 and one ground terminal TP4.
- the acoustic signal terminals TJ1 and TJ2, and TP1 and TP2 are terminals for exchanging 2-channel analog acoustic signals.
- the acoustic signal terminals TJ1 and TP1 are terminals for the L (Left) channel, and the acoustic signal terminals TJ2 and TP2 are terminals for the R (Right) channel.
- the acoustic signal terminal TJ1 is a terminal that outputs an L-channel acoustic signal
- the acoustic signal terminal TJ2 is a terminal that outputs an R-channel acoustic signal.
- the acoustic signal terminal TP1 is a terminal that receives an L-channel acoustic signal
- the acoustic signal terminal TP2 is a terminal that receives an R-channel acoustic signal.
- the microphone terminals TJ3 and TP3 are terminals for exchanging an analog acoustic signal obtained from a microphone (for example, the microphone 81 0 , which is one of microphones 81 0 to 81 4 described later).
- the ground terminals TJ4 and TP4 are terminals connected to the ground (GND).
- the acoustic signal terminals TJ1 and TP1 are connected, the acoustic signal terminals TJ2 and TP2 are connected, the microphone terminals TJ3 and TP3 are connected, and the ground terminals TJ4 and TP4 are connected. Connected.
- a driver for example, a coil and a diaphragm serving as a sound output unit that outputs sound of the L and R channels is used as an acoustic signal.
- a headset having a four-pole plug, which is provided with a transducer (which may be called a speaker) that converts sound (sound wave) as vibration (sometimes called a speaker) and a microphone.
- the plug 23 may be the same plug as the four-pole plug of the existing headset as described above, and the jack 14 may be a four-pole plug of the existing headset as described above. Corresponding 4-pole jacks can be used.
- the plug 23 can be inserted into a jack (4 pole jack) of an existing jack device such as a music player that can use an existing headset having 4 poles (having a plug).
- a plug of an existing headset with 4 poles (a plug of 4 poles) can be inserted into the jack 14.
- the acoustic signal terminals TP1 and TP2 of the plug 23 and the acoustic signal terminal of the three-pole jack are connected.
- the ground terminal TP4 of the plug 23 is connected to the ground terminal of the three-pole jack, and the microphone terminal TJ3 of the plug 23 is configured not to short-circuit the terminals. The same applies to the jack 14.
- the plug 23 is not limited to the same plug as the four-pole plug of the existing headset, and is not limited to the four-pole plug. That is, as the plug 23, for example, a three-pole plug having one (monaural) acoustic signal terminal TP1, one microphone terminal TP3, and one ground terminal TP4, two acoustic signal terminals TJ1 and TJ2, In addition to one microphone terminal TJ3 and one ground terminal TJ4, it is possible to employ a plug having five or more poles having a separate microphone terminal or a predetermined signal terminal. However, since the configuration of a plug having a large number of poles (number of terminals) is complicated, a plug having an extremely small number of poles such as 4 poles, 5 poles and 6 poles can be adopted as the plug 23. .
- a four-pole plug 23 is directly provided on the main body of the input device 20, but the four-pole plug 23 is connected via a four-core cable. Can be connected to the main body of the input device 20.
- the analog acoustic interface 12 includes a DAC (Digital Analog Converter) 31, a power amplifier (headphone amplifier) 32, and a resistor (R) 33.
- DAC Digital Analog Converter
- R resistor
- the DAC 31 receives from the signal processing block 11 digital audio signals of L and R channels, that is, for example, an audio signal of a music played back by the host device 10 functioning as a music player, or the host device 10 as a telephone.
- the sound signal of the other party's voice is supplied.
- the DAC 31 DA-converts the L and R channel digital sound signals from the signal processing block 11 to obtain L and R channel analog sound signals and supplies them to the power amplifier 32.
- the power amplifier 32 amplifies the L and R channel analog acoustic signals from the DAC 31 as necessary, and outputs them to the acoustic signal terminals TJ1 and TJ2 of the jack 14, respectively.
- the acoustic signal terminals TJ1 and TP1 are connected and the acoustic signal terminals TJ2 and TP2 are connected. Therefore, the acoustic signal terminals TJ1 and TJ2 of the jack 14 are connected.
- the analog sound signals of the L and R channels output to are output to the sound signal terminals TP1 and TP2 of the plug 23, respectively.
- One end of the resistor 33 is connected to the power source V D , and the other end is connected to the terminal 41 A of the switch 41.
- the multiplexed data interface 13 includes a switch 41, a capacitor 43, a microphone detection unit 44, a correspondence detection unit 45, an interrupter 46, a transmission / reception processing unit 47, a register 48, and an I 2 C interface (I / F) 49.
- the switch 41 has terminals 41A and 41B and is connected to the microphone terminal TJ3 of the jack 14.
- the switch 41 connects the microphone terminal TJ3 of the jack 14 and the terminal 41A or 41B by selecting the terminal 41A or 41B.
- the switch 41 is in the default state, that is, in the initial state, the standby state, the state where nothing is inserted in the jack 14, and the state where the switch 41 is not switched so as to select the terminal 41B.
- the terminal 41A is selected.
- an acoustic signal line JA is a signal line for receiving an acoustic signal # 0 of the analog microphone 81 0 outputs to be described later It is connected.
- the acoustic signal line JA connects the terminal 41A and the signal processing block 11, and when the switch 41 selects the terminal 41A (and hence the acoustic signal line JA connected to the terminal 41A), the signal processing block 11
- the sound signal line JA connected to the terminal 41A and the switch 41 are connected to the microphone terminal TJ3 of the jack 14.
- the terminal 41A is the other end of the one end connected to a power supply V D resistor 33 is also connected, the switch 41 and selects the terminal 41A, the power supply V D also, resistor 33, And, it is connected to the microphone terminal TJ3 of the jack 14 via the switch 41.
- a multiplexed data signal line JB for receiving multiplexed data transmitted from the input device 20 is connected to the terminal 41B.
- the multiplexed data signal line JB is connected to the power source V D and the transmission / reception processing unit 47. Therefore, the switch 41 is connected to the terminal 41B (and thus the multiplexed data signal connected to the terminal 41B).
- the power source V D and the transmission / reception processing unit 47 are connected to the microphone terminal TJ3 of the jack 14 via the multiplexed data signal line JB and the switch 41.
- the capacitor 43 has one end connected to the microphone terminal TJ3 of the jack 14 and the other end connected to the correspondence detection unit 45, and cuts the DC component of the signal passing through the capacitor 43.
- the microphone detection unit 44 monitors the voltage at the microphone terminal TJ3 of the jack 14.
- the microphone 81 0 of the input device 20, taking the host device 10 becomes a direct current resistance of several k ohms (component), the voltage of the microphone terminal TJ3 of the jack 14 is changed.
- the microphone detection unit 44 indicates that the microphone has been connected by the change in voltage, that is, that the plug device having a microphone such as a headset having a four-pole plug has been inserted into the jack 14. To detect. Note that the microphone detection unit 44 can detect that a microphone is connected based on a change in a signal other than a voltage, such as a current flowing in the microphone terminal TJ3, in addition to the voltage of the microphone terminal TJ3.
- the microphone detection unit 44 When detecting that the microphone is connected, the microphone detection unit 44 supplies a microphone detection signal representing the detection of the microphone to the correspondence detection unit 45.
- the correspondence detection unit 45 determines whether the plug device is a corresponding device. A handshake signal for detection is output.
- the handshake signal output from the correspondence detection unit 45 is supplied to the microphone terminal TJ3 of the jack 14 via the capacitor 43.
- the handshake signal for example, a sine wave of tens to hundreds of kHz can be employed.
- the correspondence detection unit 45 is supplied with the microphone detection signal from the microphone detection unit 44, outputs a handshake signal, and then responds to the handshake signal from the microphone terminal TJ3 of the jack 14 via the capacitor 43.
- the signal is received, it is detected that the plug device in which the plug is inserted into the jack 14 is a compatible device.
- the correspondence detecting unit 45 switches the switch 41 selecting the terminal 41A to select the terminal 41B, and The fact that the switch 41 is switched is supplied to the interrupter 46.
- the signal processing block When the interrupter 46 is supplied from the correspondence detection unit 45 that the switch 41 has been switched to select the terminal 41B, the signal processing block indicates that the corresponding device (plug) has been inserted into the jack 14. 11 is supplied.
- the interrupter 46 has inserted the corresponding device into the jack 14.
- the signal processing block 11 is supplied with the fact that the corresponding device is inserted into the jack 14 from the signal processing block 11 to the interrupter 46 periodically (or irregularly). Inquiries can be made by polling.
- the signal processing block 11 performs signal processing for the corresponding device when it is supplied from the interrupter 46 that the corresponding device has been inserted into the jack 14.
- the transmission / reception processing unit 47 is supplied with a clock from the clock generation unit 15, and the transmission / reception processing unit 47 operates in synchronization with the clock from the clock generation unit 15.
- the transmission / reception processing unit 47 receives multiplexed data supplied via the microphone terminal TJ3 of the jack 14, the switch 41, and the multiplexed data signal line JB when the switch 41 selects the terminal 41B. To do.
- the transmission / reception processing unit 47 performs an appropriate process on the multiplexed data such as demultiplexing (deserialization) (demodulation) of the multiplexed data, and performs, for example, digital data as the original data included in the multiplexed data.
- demultiplexing demultiplexing
- demodulation demodulation
- the multiplexed data includes, for example, digital acoustic signals # 0, # 1, # 2, # 3, # 4 and additional data.
- the additional data includes a switch (SW) signal indicating the operation of the switch 80 described later, device information described later, and other data.
- SW switch
- the transmission / reception processing unit 47 supplies the digital acoustic signals # 0, # 1, # 2, # 3, and # 4 and the switch signal included in the additional data to the signal processing block 11 and is included in the additional data.
- Device information and other data are supplied to the register 48 or to the signal processing block 11 via the I 2 C interface 49.
- the signal processing block 11 is connected to the digital acoustic signals # 0, # 1, # 2, # 3, # 4 supplied from the transmission / reception processing unit 47, the switch signal, and the I 2 C interface 49.
- the supplied data (information) can be used as necessary to perform various signal processing according to the device information.
- the signal processing block 11 uses, for example, digital sound signals # 1 to # 4, and performs NC (Noise Cancel) processing as described later on the sound signals of the music supplied to the DAC 31 according to the device information. Signal processing.
- the signal processing block 11 can perform processing such as beam forming as signal processing according to device information using, for example, digital acoustic signals # 01 to # 4.
- the transmission / reception processing unit 47 receives the multiplexed data as described above, and receives a request supplied from the signal processing block 11 via the I 2 C interface 49. In response to this, a command for the corresponding device is transmitted to the plug device which is a corresponding device in which a plug is inserted into the jack 14 via the multiplexed data signal line JB, the switch 41, and the microphone terminal TJ3 of the jack 14.
- the register 48 temporarily stores device information and the like supplied from the transmission / reception processing unit 47.
- the I 2 C interface 49 functions as an interface for connecting the transmission / reception processing unit 47 and the signal processing block 11 with I 2 C (Inter-Integrated Circuit) specifications.
- analog acoustic interface 21 As a headset, analog acoustic interface 21, a driver 61L and 61R, the switch (button) 80, and has a microphone 81 0.
- the drivers 61L and 61R are drivers (headphone drivers) as sound output units that output sound (for example, transducers configured by a coil and a diaphragm, etc., for converting sound signals into sound (sound waves) as air vibrations. ), And outputs (sounds) sounds corresponding to the sound signals supplied from the sound signal terminals TP1 and TP2 of the plug 23, respectively.
- the acoustic signal terminals TJ1 and TP1 are connected, the acoustic signal terminals TJ2 and TP2 are connected, and, for example, reproduced by the host device 10
- the acoustic signal of the music is output from the signal processing block 11 to the acoustic signal terminals TP1 and TP2 of the plug 23 via the DAC 31, the power amplifier 32, and the jack 14.
- the drivers 61L and 61R output sounds corresponding to sound signals such as music played on the host device 10.
- the switch 80 is operated by the user and is operated or not operated, and the switch signal (as viewed from the connection point PS) as a (DC) voltage of the connection point PS to which the switch 80 is connected.
- the impedance of the switch 80 is changed.
- the switch signal (H or L level) of the switch 80 is supplied to the terminal 71A of the switch 71 and the transmission processing unit 78.
- Microphone 81 the sound (sound waves) which is a physical quantity, a transducer for converting an acoustic signal which is an electric signal, and outputs the acoustic signal of an analog corresponding to sound input to the microphone 81 0.
- the microphone 81 can be used as an audio microphone for the purpose of collecting sound of the voice of the user mounting the input device 20 as a headset.
- connection point PS is the terminal 71A of the switch 71 It is connected.
- the switch signal of the switch 80 is superimposed on the acoustic signal of an analog microphone 81 0 outputs are supplied to a terminal 71A of the switch 71.
- the multiplexed data interface 22 includes a switch 71, a capacitor 72, a correspondence detection unit 73, an LDO (Low Drop-Out regulator) 74, a control unit 75, a PLL (Phase Lock Loop) 77, and a transmission.
- LDO Low Drop-Out regulator
- PLL Phase Lock Loop
- ADC Analog Digital Converter
- the switch 71 has terminals 71A and 71B and is connected to the microphone terminal TP3 of the plug 23.
- the switch 71 connects the microphone terminal TP3 of the plug 23 and the terminal 71A or 71B by selecting the terminal 71A or 71B.
- the switch 71 selects the terminal 71A among the terminals 71A and 71B by default.
- the terminal 71A, the acoustic signal line PA is connected a signal line for transmitting an acoustic signal # 0 of the analog microphone 81 0 outputs.
- the acoustic signal line PA connects the terminal 71A and the connection point PS.
- the switch 71 selects the terminal 71A (and thus the acoustic signal line PA connected to the terminal 71A)
- the connection point PS is connected to the terminal 71A. Is connected to the microphone terminal TP3 of the plug 23 via the acoustic signal line PA connected to the switch and the switch 71.
- the switch signal of the switch 80 is superimposed, the acoustic signal of the analog microphone 81 0 outputs the acoustic signal line PA, and, via a switch 71 which selects the terminal 71A, the plug It is output to 23 microphone terminals TP3.
- a multiplexed data signal line PB for transmitting multiplexed data output from the transmission processing unit 78 to the host device 10 is connected to the terminal 71B.
- the multiplexed data signal line PB is connected to the control unit 75, the PLL 77, and the transmission processing unit 78. Therefore, the switch 71 is connected to the terminal 71B (and thus to the multiplexing connected to the terminal 71B).
- the control unit 75, the PLL 77, and the transmission processing unit 78 are connected to the microphone terminal TP3 of the plug 23 via the multiplexed data signal line PB and the switch 71.
- an LDO 74 is connected to the terminal 71B.
- the switch 71 selects the terminal 71B, the LDO 74 is also connected to the microphone terminal TP3 of the plug 23 via the switch 71. Is done.
- the capacitor 72 has one end connected to the microphone terminal TP3 of the plug 23 and the other end connected to the correspondence detection unit 73, and cuts the DC component of the signal passing through the capacitor 72.
- the correspondence detection unit 73 When the correspondence detection unit 73 receives a handshake signal from the microphone terminal TP3 of the plug 23 via the capacitor 72, the correspondence detection unit 73 detects that the jack device having the jack into which the plug 23 is inserted is a corresponding device.
- the correspondence detecting unit 73 switches the switch 71 selecting the terminal 71A so as to select the terminal 71B, and inputs Similar to the received handshake signal to the microphone terminal TP3 of the plug 23 via the capacitor 72 in order to notify the jack device having the jack into which the plug 23 is inserted that the device 20 is a compatible device, or Output handshake signals with different frequencies.
- the LDO 74 is a voltage regulator, generates a predetermined voltage from a signal supplied from the microphone terminal TP3 of the plug 23 via the switch 71, and supplies power as a power source via the resistor 83 i to the amplifier 82 i or the like.
- the control unit 75 the transmission processing unit 78, the ADC 84 i , and other blocks of the multiplexed data interface 22 that require power.
- the multiplexed data interface 22 of the input device 20 operates upon receiving power supply from the host device 10 (its power supply V D ).
- signal lines for the LDO 74 to supply power to each block as a power source are omitted as appropriate in order to avoid complication of the figure.
- the control unit 75 has a built-in register 76, and performs processing according to the stored value of the register 76.
- control unit 75 registers in accordance with a signal (command) supplied from the microphone terminal TP3 of the plug 23 via the switch 71 (selecting the terminal 71B) and the multiplexed data signal line PB. Data is written to 76, data is read from the register 76 and nonvolatile memory 85, and other processing is performed.
- the control unit 75 reads the data from the register 76 and supplies it to the transmission processing unit 78.
- the data from the control unit 75 is included in the multiplexed data and transmitted from the microphone terminal TP3 of the plug 23 via the multiplexed data signal line PB and the switch 71.
- control unit 75 controls the transmission processing unit 78 to read data from the nonvolatile memory 85 and includes the multiplexed data signal in the multiplexed data. Transmission is performed from the microphone terminal TP3 of the plug 23 via the line PB and the switch 71.
- the control unit 75 controls other necessary blocks of the input device 20 as necessary. Signal lines for the control unit 75 to control necessary blocks are omitted as appropriate in order to avoid complication of the drawing.
- the PLL 77 has a jack having a jack into which the plug 23 is inserted via the microphone terminal TP3 of the plug 23, the switch 71, and the multiplexed data signal line PB when the switch 71 selects the terminal 71B.
- a signal is supplied from the device (corresponding device).
- the PLL 77 generates a clock synchronized with a signal supplied via the microphone terminal TP3 of the plug 23, the switch 71, and the multiplexed data signal line PB, and supplies the clock to the transmission processing unit 78 and other necessary blocks.
- the transmission processing unit 78 operates synchronously with the clock supplied from PLL77, the switch signal from the switch 80, the digital sound signal #i, data read from the register 76 from the ADC 84 i, and non-volatile
- the data (device information) read from the memory 85 is (time-division) multiplexed (serialized) (modulated) and subjected to other necessary processing, and the resulting multiplexed data is converted into a multiplexed data signal line PB. And from the microphone terminal TP3 of the plug 23 via the switch 71.
- the multiplexed data includes digital acoustic signals # 0, # 1, # 2, # 3, # 4 and additional data.
- the switch signal, the data read from the register 76, and the data read from the nonvolatile memory 85 are additional data.
- the microphone 81 i is a transducer that converts a sound (sound wave) that is a physical quantity into an acoustic signal that is an electrical signal, and outputs an analog acoustic signal #i corresponding to the sound #i input to the microphone 81 i .
- the microphone 81 for example, as described above, can be used as an audio microphone for the purpose of collecting sound of the voice of the user mounting the input device 20 as a headset.
- the microphones 81 1 to 81 4 can be used as NC microphones for the purpose of collecting sound such as noise used in the NC processing performed in the signal processing block 11 of the host device 10, for example.
- the analog acoustic signal #i output from the microphone 81 i is supplied to the amplifier 82 i .
- Amplifier 82 i amplifies the acoustic signal #i analog from the microphone 81 i, and supplies the ADC 84 i.
- the resistor 83 i is connected between the output terminal of the LDO 74 and the connection point between the microphone 81 i and the amplifier 82 i .
- the ADC 84 i performs AD conversion of the analog acoustic signal #i from the amplifier 82 i and supplies the digital acoustic signal #i obtained as a result to the transmission processing unit 78.
- AD conversion of the ADC 84 i for example, ⁇ modulation as 1-bit AD conversion can be adopted.
- the non-volatile memory 85 is, for example, an OTP (One Time Programmable) memory or an EPROM (Erasable Programmable Read Only Memory), and the non-volatile memory 85 stores device information.
- OTP One Time Programmable
- EPROM Erasable Programmable Read Only Memory
- the device information is information related to the input device 20, and the device information includes a vendor ID (Identification) that identifies the manufacturer of the input device 20 and a product ID that identifies the model of the input device 20 (individual). Can be included.
- the device information can include configuration function information indicating the configuration, function, and usage of the input device 20.
- the configuration function information for example, the fact that the input device 20 is a headset or the like, or the number of transducers such as the microphone 81 i provided in the input device 20 can be adopted.
- the device information is optimal (or appropriate) for the input device 20 in the signal processing block 11. It is possible to include processing information or the like for performing various processing.
- the processing information for example, when the NC processing is performed in the signal processing block 11 of the host device 10 as a smartphone functioning as a music player, the optimal NC processing is performed for the input device 20 as a headset. Therefore, the NC processing algorithm, the filter coefficient of the filter used in the NC processing, the characteristics of the microphone 81 i that can be used to obtain the filter coefficient, the characteristics of the drivers 61L and 61R, etc. Can be adopted.
- the input device 20 is provided with one switch 80, but the input device 20 may be provided with two or more switches (in parallel with the connection point PS). Further, the input device 20 can be configured without providing a switch.
- the input device 20 although five microphone 81 0 to 81 4 are provided, the input device 20 may be provided with a plurality of microphones of a number other than five.
- the input device 20 may be provided with a transducer that converts a physical quantity into an electrical signal, that is, an acceleration sensor, a touch sensor, a biological sensor that senses a physical quantity related to a living body such as body temperature and pulse, and the like. it can.
- FIG. 3 is a flowchart for explaining processing of the host device 10 and the input device 20 of FIG.
- step S11 the switch 41 selects the terminal 41A by default.
- step S21 the switch 71 selects the terminal 71A by default.
- the microphone detection unit 44 is a plug device having the plug 23 inserted into the jack 14. detecting the microphone 81 0 as the audio microphone present in the input device 20.
- the microphone 23 is connected to the power source V D via the microphone terminal TP3 of the plug 23, the microphone terminal TJ3 of the jack 14, the switch 41 (which selects the terminal 41A), and the resistor 33.
- the microphone 81 0 of the input device 20, taking the host device 10 becomes a direct current resistance of several k ohms (component), the voltage of the microphone terminal TJ3 of the jack 14 is changed.
- Microphone detection unit 44 by the change of the voltage, the microphone 81 0 is connected, in turn, detects the microphone 81 0.
- Microphone detecting unit 44 detects the microphone 81 0, supplies a microphone detection signal indicative of detection of the microphone 81 0, the correspondence detection section 45.
- the correspondence detection unit 45 transmits a handshake signal in step S13.
- the handshake signal transmitted by the correspondence detection unit 45 reaches the correspondence detection unit 73 of the input device 20 via the capacitor 43, the microphone terminal TJ3 of the jack 14, the microphone terminal TP3 of the plug 23, and the capacitor 72.
- step S22 in the input device 20, the correspondence detection unit 73 receives the handshake signal transmitted from the correspondence detection unit 45 of the host device 10 as described above.
- the correspondence detection unit 73 detects (recognizes) that the host device 10 that is the jack device having the jack 14 with the plug 23 inserted is a compatible device by receiving the handshake signal.
- the correspondence detection unit 73 determines that the input device 20 is a compatible device in step S23.
- a handshake signal for notifying a jack device having a jack into which the plug 23 is inserted is transmitted.
- step S24 the correspondence detection unit 73 switches the switch 71 that has selected the terminal 71A to select the terminal 71B.
- the switch 71 When the switch 71 is switched to select the terminal 71B, the microphone terminal TP3 of the plug 23 is connected to the LDO 74 via the switch 71 (selecting the terminal 71B).
- the microphone terminal TP3 of the plug 23 is connected to the control unit 75, the PLL 77, and the transmission processing unit 78 via the switch 71 and the multiplexed data signal line PB.
- the handshake signal transmitted by the correspondence detection unit 73 in step S23 reaches the correspondence detection unit 45 of the host device 10 via the capacitor 72, the microphone terminal TP3 of the plug 23, the microphone terminal TJ3 of the jack 14, and the capacitor 43. .
- step S14 in the host device 10, the correspondence detection unit 45 receives the handshake signal transmitted from the correspondence detection unit 73 of the input device 20 as described above.
- the correspondence detection unit 45 detects (recognizes) that the input device 20 which is a plug device having the plug 23 inserted into the jack 14 is a compatible device by receiving the handshake signal.
- the correspondence detection unit 45 selects the switch 41 that selects the terminal 41A and the terminal 41B. In addition, the fact that the switch 41 is switched is supplied to the interrupter 46.
- the signal processing block When the interrupter 46 is supplied from the correspondence detection unit 45 that the switch 41 has been switched to select the terminal 41B, the signal processing block indicates that the corresponding device (plug) has been inserted into the jack 14. 11 is supplied.
- the microphone terminal TJ3 of the jack 14 is transmitted / received via the switch 41 (selecting the terminal 41B) and the multiplexed data signal line JB. processing unit 47, and is connected to a power supply V D.
- the microphone terminal TJ3 of the jack 14 is connected to the power source V D via the switch 41 and the multiplexed data signal line JB, so that the power source V D is multiplexed with the host device 10.
- the LDO 74 is connected to the LDO 74 via the data signal line JB, the switch 41, the microphone terminal TJ3 of the jack 14, and the microphone terminal TP3 of the plug 23 of the input device 20 and the switch 71 (selecting the terminal 71B). Connected.
- the LDO 74 obtains power from the power source V D and needs a power source such as the amplifier 82 i of the input device 20.
- the supply of power to be a power source is started to an active block.
- the transmission / reception processing unit 47 starts from the clock generation unit 15 in step S16.
- the transmission of the clock (including the signal) is started in synchronization with the clock.
- the clock transmitted from the transmission / reception processing unit 47 is transmitted via the multiplexed data signal line JB, the switch 41, the microphone terminal TJ3 of the jack 14, the microphone terminal TP3 of the plug 23, the switch 71, and the multiplexed data signal line PB. Reach PLL 77.
- step S25 the PLL 77 starts to operate in accordance with the clock transmitted from the transmission / reception processing unit 47 as described above.
- the control unit 75 When the PLL 77 enters a so-called locked state, the control unit 75 generates a clock synchronized with the clock from the transmission / reception processing unit 47. Or the transmission processing unit 78 or the like.
- step S 26 the transmission processing unit 78 starts operation in synchronization with the clock from the PLL 77, switches the signal from the switch 80, the digital acoustic signal #i from the ADC 84 i , the data read from the register 76, Further, the data read from the nonvolatile memory 85 is multiplexed, and the resulting multiplexed data is converted into a multiplexed data signal line PB, a switch 71, a microphone terminal TP3 of the plug 23, a microphone terminal TJ3 of the jack 14, and a switch. 41 and a process of transmitting to the transmission / reception processing unit 47 via the multiplexed data signal line JB is started.
- step S17 the transmission / reception processing unit 47 starts receiving multiplexed data transmitted from the transmission processing unit 78 as described above.
- the input device 20 detects whether or not the jack device having the jack into which the plug 23 is inserted is a compatible device capable of handling multiplexed data, and when the jack device is a compatible device. While the multiplexed data is transmitted through the plug 23, the host device 10 detects whether or not the plug device having the plug inserted into the jack 14 is a compatible device, and the plug device is a compatible device. In this case, since the multiplexed data transmitted from the plug device that is the corresponding device is received via the jack 14, the input device 20 as the plug device that is the compatible device is used as the jack device that is the compatible device. Transmission / reception of multiplexed data to / from the host device 10 It can be done to ease.
- the audio signals # 0 to # 4 to be transmitted can be included in the multiplexed data and transmitted / received.
- the host device 10 detects whether or not the plug device having the plug inserted into the jack 14 is a compatible device. When the plug device is a compatible device, the host device 10 selects the switch 41 that selects the terminal 41A. Therefore, when the plug device is not a compatible device, the switch 41 selecting the terminal 41A remains in the state of selecting the terminal 41A.
- the host device 10 can be used as an existing plug device having a four-pole plug, which is not a compatible device, of course, when the corresponding input device 20 (plug 23) is connected (to the jack 14).
- the existing headset can be used so-called backward compatibility.
- the switch 71 selecting the terminal 71A is selected. Therefore, when the jack device is not a corresponding device, the switch 71 selecting the terminal 71A remains in the state where the terminal 71A is selected.
- the input device 20 is connected to the host device 10 (jack 14) which is a corresponding device (of which the plug 23) is connected, as an existing jack device having a four-pole jack, which is not a compatible device, For example, even if it is a case where it connects with the existing smart phone, it has the backward compatibility that the existing smart phone can be used.
- the host device 10 can pretend to be an existing smartphone or the like by not operating the multiplexed data interface 13.
- the switch 41 remains in the default state, that is, the terminal 41A to which the acoustic signal line JA is connected remains selected, and the microphone terminal TJ3 of the jack 14 is The state remains connected to the acoustic signal line JA to which the resistor 33 and the signal processing block 11 are connected.
- the switch 71 remains in the default state, that is, the terminal 71A to which the acoustic signal line PA is connected remains selected, and the microphone terminal TP3 of the plug 23 is will remain switches 80 and the microphone 81 0 is connected to the connected audio signal line PA connected to the connection point PS.
- the simulated input device 20 when an existing headset that is not a compatible device (the simulated input device 20) is connected to the host device 10 that is a compatible device, and when the input device 20 that is a compatible device is an existing smartphone that is not a compatible device ( A case where the host device 10) is assumed to be connected to the network will be described.
- the microphone 81 0 is used in the microphone detection unit 44 as in the standard case. Is detected, and a handshake signal is transmitted from the correspondence detection unit 45.
- the handshake signal from the correspondence detection unit 45 reaches the correspondence detection unit 73 of the input device 20 through the capacitor 43, the microphone terminal TJ3 of the jack 14, the microphone terminal TP3 of the plug 23, and the capacitor 72.
- the correspondence detection unit 73 since the multiplexed data interface 22 does not operate in the input device 20 simulated by the existing headset, the correspondence detection unit 73 does not return a handshake signal unlike the standard case.
- the correspondence detection unit 45 cannot receive a handshake signal, it detects (recognizes) that the input device 20 simulated by the existing headset is not a compatible device.
- the correspondence detection unit 45 does not switch the switch 41 that selects the terminal 41A, but keeps the terminal 41A selected, whereby the terminal TJ3 of the jack 14 (the terminal 41A is selected).
- the switch 41 and the resistor 33 are connected to the power source V D and to the acoustic signal line JA (becomes connected).
- the switch 71 keeps selecting the terminal 71A to which the acoustic signal line PA is connected, so the microphone terminal TP3 of the plug 23 is the switch 80 and the microphone. 81 0 is connected to the acoustic signal line PA that is connected to connection point PS.
- the acoustic signal line JA, the switch 41, the microphone terminal TJ3 of the jack 14, the microphone terminal TP3 of the plug 23, the switch 71, and the path of the acoustic signal line PA are connected to the power source via the resistor 33 that prevents overcurrent. A voltage of V D is applied.
- the sound signal # 0 of the analog microphone 81 0 is output connection point PS, the acoustic signal line PA, switch 71, microphone terminal TP3 and TJ3, switch 41, and, via the acoustic signal line JA, signal processing block 11 is supplied.
- Signal processing block 11 is supplied as described above, the sound signal # 0 of the analog microphone 81 0 outputs, for example, performed as necessary signal processing of the AD conversion and the like, for example, telephone (transmitter ).
- the switch signal switch 80 is outputted in the form to be superimposed on the sound signal # 0 of the analog microphone 81 0 outputs, connection point PS, the acoustic signal line PA, switch 71, microphone terminal TP3 and TJ3, switch 41, In addition, the signal is supplied to the signal processing block 11 via the acoustic signal line JA.
- the signal processing block 11 detects the switch signal based on the DC component of the analog acoustic signal # 0 supplied via the acoustic signal line JA, that is, detects the operation of the switch 80, and operates the switch 80.
- the signal processing according to is performed.
- the acoustic signal of the music reproduced by the host device 10 the acoustic signal of the voice received by the host device 10 as a telephone
- the analog acoustic interface 12 of the host device 10 the acoustic signal terminals TJ1 and TJ2 of the jack 14, and
- the analog sound interface 21 of the input device 20 simulated by the existing headset is supplied via the sound signal terminals TP1 and TP2 of the plug 23.
- the drivers 61L and 61R output the sound corresponding to the sound signal of the music reproduced by the host device 10, the sound signal of the sound received by the host device 10 as a telephone, and the like.
- the switch 41 is in a state where the terminal 41A is selected.
- the existing 4-pole headset having a microphone can be used in the same manner as when connected to an existing smartphone or the like without being limited in its function. Therefore, the host device 10 that is a compatible device has backward compatibility.
- the input device 20 is configured by the analog acoustic interface 21 and the plug 23 without the microphone terminal TP3, so that it can be imitated by an existing headphone having a three-pole plug.
- the existing headphones can be used in the same manner as when connected to an existing music player or the like having a three-pole jack.
- the correspondence detection unit 73 cannot receive a handshake signal, and thus it is detected (recognized) that the host device 10 pretending to be an existing smartphone is not a compatible device.
- the correspondence detection unit 73 does not switch the switch 71 that selects the terminal 71A, but keeps the terminal 71A selected, whereby the terminal TP3 of the plug 23 (the terminal 71A is selected). via the switch 71, it remains connected state to the acoustic signal line PA of switch 80 and the microphone 81 0 is connected to connection point PS.
- the switch 41 since the switch 41 remains selected with the terminal 41A, the terminal TJ3 of the jack 14 is the switch 41 (which selects the terminal 41A) and the resistance It is connected to the power source V D through 33 and to the acoustic signal line JA (becomes connected).
- the host device 10 that is the compatible device described above is simulated by an existing headset. The same state as when the input device 20 is connected is obtained.
- the existing smartphone is connected to an existing headset or the like without being limited in function. It can be used in the same way.
- the input device 20 that is a compatible device When an input device 20 that is a compatible device is connected to an existing smartphone, the input device 20 that is a compatible device functions as a four-pole existing headset having a microphone.
- the switch 71 is in a state in which the terminal 71A is selected.
- Some input devices 20 function as a four-pole existing headset with a microphone and are therefore backward compatible.
- the input device 20 which is a corresponding device is connected to an existing music player having a three-pole jack provided with terminals corresponding to the acoustic signal terminals TJ1 and TJ2 and the ground terminal TJ4, the corresponding device An input device 20 functions as an existing three-pole headphone.
- multiplexed data can be transmitted and received, so the jacks 14 having a limited number of poles (number of terminals), and Via the plug 23, a signal exceeding the number of poles can be included in the multiplexed data and transmitted / received between the host device 10 and the input device 20.
- the present invention microphone 81 0 to 81 4 # 0 microphone audio signal to AD convert
- microphone sound signal output # 4 the switch signal switch 80 is outputted, and, stored in the nonvolatile memory 85
- Device information and other data are multiplexed into multiplexed data, and the multiplexed data is transmitted / received via the microphone terminals TJ3 and TP3, which are one terminal of four poles, to be supplied to the drivers 61L and 61R.
- Sound signal terminals TJ1 and TJ2 and TP1 and TP2 through which channel and R channel sound signals (hereinafter also referred to as speaker sound signals) are transmitted and received, and ground terminals TJ4 and TP4 connected to the ground are not particularly changed.
- the stored device information and other data can be transmitted and received between the host device 10 and input device 20.
- the input device 20, a to 0 to a plurality of microphones 81 81 4 microphone sound signal # 0 to output # 4, etc. can be said to be a device that functions as an interface for inputting the host device 10.
- the S & H sample and hold
- switch + S & H method a method of multiplexing and transmitting and receiving a plurality of acoustic signals as analog signals.
- the switch + S & H method S & H is periodically performed for a plurality of acoustic signals, and therefore, the S & H of the acoustic signals at the same time cannot be performed for each of the plurality of acoustic signals. Therefore, when signal processing such as beam forming is performed using a plurality of acoustic signals multiplexed by the switch + S & H method, for example, a plurality of microphones obtained by microphones arranged at different positions such as left and right are used. As for the acoustic signal, the accuracy of beamforming may deteriorate because there is no acoustic signal at the same time in the multiplexed data.
- an ADC that AD-converts each of the plurality of acoustic signals is required on the host device 10 side.
- the configuration of the host device 10 and the input device 20 is compared with a case where an analog acoustic signal is AD-converted into 1 bit by ⁇ modulation and multiplexed. It may become complicated and disadvantageous in terms of power consumption.
- the host device 10 operates in synchronization with the clock output from the clock generation unit 15.
- the input device 20 operates in synchronization with the clock generated by the PLL 77 in synchronization with the clock output from the clock generation unit 15 of the host device 10.
- the host device 10 and the input device 20 operate in synchronization.
- the ADC 84 i performs AD conversion using, for example, a clock generated by the PLL 77 in synchronization with a clock output from the clock generation unit 15 of the host device 10 as a sampling timing.
- the switch 41 can select the terminal 41 ⁇ / b> A when the plug 23 is not inserted into the jack 14.
- the switch 71 can select the terminal 71A.
- the transmission / reception processing unit 47 separates (demultiplexes) the acoustic signal included in the multiplexed data from the multiplexed data.
- the clock generation unit 15 performs AD conversion on the number of acoustic signals based on the number of microphones 81 i included in the device information included in the device information 20 to generate multiplexed data.
- a clock having a necessary and sufficient frequency (period) can be generated.
- bidirectional communication is performed between the host device 10 and the input device 20.
- data (signal) transmitted from the input device 20 to the host device 10 includes, for example, multiplexed data.
- the multiplexed data includes a microphone audio signal #i output from the microphone 81 i (if the input device 20 is provided with a transducer other than the microphone 81 i , a signal (digital signal) output from the transducer), a switch 80 includes a switch signal output from 80, device information stored in the nonvolatile memory 85, and the like.
- data (signal) transmitted from the host device 10 to the input device 20 includes, for example, a clock generated by the clock generation unit 15, There are commands for the control unit 75 and the like.
- the command for the control unit 75 for example, a register 76 and reading and writing data to the nonvolatile memory 85, the sleep input device 20 (e.g., such as ADC 84 i, the power supply to the non-minimum block block In a stopped state) and a command for instructing the input device 20 to return (start) from the sleep state.
- the sleep input device 20 e.g., such as ADC 84 i, the power supply to the non-minimum block block In a stopped state
- control unit 75 since the control unit 75 performs processing in accordance with the stored value of the register 76, a command other than the data read / write command to the register 76 and the nonvolatile memory 85, for example, the input device 20 is set in the sleep state. And a command for returning the input device 20 from the sleep state can be performed by writing a predetermined value in the register 76 instead of preparing a dedicated command.
- an analog microphone and a digital microphone can be used in combination.
- FIG. 4 is a block diagram illustrating a second detailed configuration example of the host device 10 and the input device 20.
- the input device 20 is configured in the same manner as in FIG.
- the host device 10 includes a signal processing block 11, a clock generation unit 15, a DAC 31, a power amplifier 32, a capacitor 43, a microphone detection unit 44, a correspondence detection unit 45, an interrupter 46, a transmission / reception processing unit 47, and a register 48. And having the I 2 C interface 49 is common to the case of FIG.
- the host device 10 is different from the case of FIG. 2 in that the resistor 33 and the switch 41 are not provided.
- the analog acoustic interface 12 is different from the case of FIG. 2 in that it has the DAC 31 and the power amplifier 32 and is common to the case of FIG.
- the multiplexed data interface 13 includes a capacitor 43, a microphone detection unit 44, a correspondence detection unit 45, an interrupter 46, a transmission / reception processing unit 47, a register 48, and an I 2 C interface 49. 2 is different from the case of FIG. 2 in that the switch 41 is not provided.
- the host device 10 does not have the switch 41. Therefore, in FIG. 2, the host device 10 does not have the acoustic signal line JA that connects the terminal 41A of the switch 41 and the signal processing block 11. .
- the multiplexed data signal line JB is connected to the microphone terminal TJ3 of the jack 14 via the switch 41 as shown in FIG. Instead, it is directly connected to the microphone terminal TJ3 of the jack 14.
- the host device 10 does not include the resistor 33, the switch 41, and the acoustic signal line JA. Therefore, the operation when the switch 41 selects the terminal 41 ⁇ / b> B in FIG. 2. The operation when the switch 41 selects the terminal 41A cannot be performed.
- the host device 10 can receive the multiplexed data from the input device 20 because the operation can be performed when the switch 41 selects the terminal 41B in FIG. 2 as described above. Can do. Therefore, in FIG. 4, the host device 10 is a corresponding device.
- the backward compatibility of the host device 10 is ensured by the switch 41 selecting the terminal 41A in FIG. 2, so that the operation when the switch 41 selects the terminal 41A can be performed.
- the host device 10 of FIG. 4 that is not possible is not backward compatible.
- the sound of the jack 14 is transmitted from the signal processing block 11 via the DAC 31 and the power amplifier 32. Sound corresponding to the speaker sound signal supplied to the signal terminals TJ1 and TJ2 can be output from the existing headset.
- the microphone sound signal of the existing headset is supplied to the microphone terminal TJ3 of the jack 14, the microphone sound signal is not accepted (not processed) by the host device 10 of FIG.
- the host device 10 shown in FIG. 4 that is, a compatible device, but does not have backward compatibility
- the input device 20 shown in FIG. 4 ie, an input that is a compatible device and has backward compatibility.
- the handshake signals are transmitted and received between the correspondence detection units 45 and 73 in the same manner as in the standard case, so that the host device 10 and the input device 20 can mutually , It is detected that the counterpart device is a compatible device.
- the host device 10 performs multiplexing between the host device 10 and the input device 20 in the same manner as in the standard case except that the switch 41 is not switched so as to select the terminal 41B. Data is sent and received.
- FIG. 5 is a block diagram illustrating a third detailed configuration example of the host device 10 and the input device 20.
- the host device 10 is configured in the same manner as in FIG.
- the input device 20 includes drivers 61L and 61R, a capacitor 72, a correspondence detection unit 73, an LDO 74, a control unit 75, a PLL 77, a transmission processing unit 78, a switch 80, a microphone 81 0 to 81 4 , and an amplifier 82 0. 2 to 82 4 , resistors 83 0 to 83 4 , ADCs 84 0 to 84 4 , and nonvolatile memory 85.
- the input device 20 is different from the case of FIG. 2 in that the switch 71 is not provided.
- the analog acoustic interface 21 in that it has a driver 61L and 61R, in common with the case of FIG. 2, as a component of an analog acoustic interface 21, switch 80, and does not include the microphone 81 0 This is different from the case of FIG.
- the multiplexed data interface 13 includes a capacitor 72, a correspondence detection unit 73, an LDO 74, a control unit 75, a PLL 77, a transmission processing unit 78, a switch 80, microphones 81 0 to 81 4 , and amplifiers 82 0 to 82 4. , Resistors 83 0 to 83 4 , ADCs 84 0 to 84 4 , and nonvolatile memory 85, which is the same as that in FIG. 2, and is different from that in FIG. 2 in that the switch 71 is not provided. .
- the input device 20 does not include the switch 71, and therefore does not include the acoustic signal line PA that connects the terminal 71 ⁇ / b> A of the switch 71 and the connection point PS.
- the multiplexed data signal line PB is connected to the microphone terminal TP3 of the plug 23 via the switch 71 as shown in FIG. Instead, it is directly connected to the microphone terminal TP3 of the plug 23.
- the input device 20 does not include the switch 71 and the acoustic signal line PA in FIG. 5, the operation when the switch 71 selects the terminal 71 ⁇ / b> B in FIG. 2 is performed. However, the operation when the switch 71 selects the terminal 71A cannot be performed.
- the input device 20 can perform the operation when the switch 71 selects the terminal 71 ⁇ / b> B in FIG. 2, so that multiplexing is performed via the microphone terminal TP ⁇ b> 3 of the plug 23. Data can be transmitted. Therefore, in FIG. 5, the input device 20 is a corresponding device.
- the input device 20 cannot perform the operation when the switch 71 selects the terminal 71A in FIG.
- the backward compatibility of the input device 20 is ensured by the switch 71 selecting the terminal 71A in FIG. 2, so that the operation when the switch 71 selects the terminal 71A can be performed.
- the input device 20 of FIG. 5 which is not possible is not backward compatible.
- the plug when the input device 20 is connected to, for example, an existing smartphone having a four-pole jack corresponding to a four-pole existing headset having a microphone, the plug is removed from the existing smartphone.
- the sound corresponding to the speaker sound signal supplied to the 23 sound signal terminals TP1 and TP2 can be output from the drivers 61L and 61R.
- the multiplexed data is accepted by the existing smartphone. No (not processed).
- acoustic signal # 0 of the analog microphone 81 0 is output because they are not supplied to the microphone terminal TP3 of the plug 23, to an existing smart phone
- analog acoustic signal # 0 cannot be input.
- the input device 20 shown in FIG. 5, that is, a compatible device but not having backward compatibility is the host device 10 shown in FIG. 5, that is, a compatible device and having backward compatibility.
- the handshake signals are transmitted and received between the correspondence detection units 45 and 73 in the same manner as in the standard case, so that the host device 10 and the input device 20 can communicate with each other. , It is detected that the counterpart device is a compatible device.
- the input device 20 performs multiplexing between the input device 20 and the host device 10 in the same manner as in the standard case except that the switch 71 is not switched so as to select the terminal 71B. Data is sent and received.
- FIG. 6 is a block diagram illustrating a fourth detailed configuration example of the host device 10 and the input device 20.
- the host device 10 is configured in the same manner as in FIG. 4, and the input device 20 is configured in the same manner as in FIG. 5.
- the host device 10 and the input device 20 are both compatible devices, but do not have backward compatibility.
- the handshake between the correspondence detection units 45 and 73 is performed in the same manner as in the standard case.
- the host device 10 and the input device 20 detect that the other device is a compatible device.
- the host device 10 does not switch so that the switch 41 selects the terminal 41B, and the input device 20 switches so that the switch 71 selects the terminal 71B.
- the multiplexed data is transmitted / received between the input device 20 and the host device 10 in the same manner as in the standard case except that there is no data.
- FIG. 7 is a block diagram illustrating a fifth detailed configuration example of the host device 10 and the input device 20.
- the host device 10 is configured in the same manner as in FIG. 6 except that the capacitor 43, the microphone detection unit 44, the correspondence detection unit 45, and the interrupter 46 are not provided.
- the input device 20 is configured in the same manner as in FIG. 6 except that the capacitor 72 and the correspondence detection unit 73 are not provided.
- the host device 10 does not have the correspondence detection unit 45, it is not detected whether or not the plug device having the plug inserted into the jack 14 is a correspondence device.
- the input device 20 does not have the correspondence detection unit 73, it is not detected whether or not the jack device having the jack into which the plug 23 is inserted is a correspondence device.
- the host device 10 in FIG. 7 does not have backward compatibility, similar to the host device 10 in FIG.
- the input device 20 in FIG. 7 does not have backward compatibility, like the input device 20 in FIG.
- a plurality of analog acoustic signals are not converted into a plurality of digital acoustic signals after being AD converted, but are analogized.
- a method of multiplexing a plurality of analog audio signals as analog signals can be said to be a digital method.
- the host device 10 and the input device 20 in FIG. 7 do not have backward compatibility. This also applies to the host device 10 in FIGS. 4 and 6 and the input device 20 in FIGS. 5 and 6.
- the host device 10 and the input device 20 are preferably configured as shown in FIG.
- FIG. 8 is a block diagram illustrating a sixth detailed configuration example of the host device 10 and the input device 20.
- the host device 10 includes a signal processing block 11, a clock generation unit 15, a DAC 31, a power amplifier 32, a resistor 33, a switch 41, an interrupter 46, a transmission / reception processing unit 47, a register 48, and an I 2 C interface 49. This is common to the case of FIG.
- the host device 10 is not provided with the capacitor 43, the microphone detection unit 44, and the correspondence detection unit 45, and the plug detection unit 101, the authentication pattern output unit 102, and the pattern detection unit 103 It is different from the case of FIG. 2 in that it is newly provided.
- the analog acoustic interface 12 is configured in the same manner as in FIG.
- the multiplexed data interface 13 includes a switch 41, an interrupter 46, a transmission / reception processing unit 47, a register 48, an I 2 C interface 49, a plug detection unit 101, an authentication pattern output unit 102, and The pattern detection unit 103 is configured.
- the input device 20 includes drivers 61L and 61R, a switch 71, an LDO 74, a control unit 75, a PLL 77, a transmission processing unit 78, a switch 80, a microphone 81 0 to 81 4 , an amplifier 82 0 to 82 4 , a resistor. It is common to the case of FIG. 2 in that it has 83 0 to 83 4 , ADCs 84 0 to 84 4 , and a nonvolatile memory 85.
- the input device 20 is not provided with a capacitor 72 and a correspondence detection unit 73, but is provided with a power detection unit 111 and an authentication pattern output unit 112. This is different from the case of 2.
- the analog acoustic interface 21 is configured in the same manner as in FIG.
- the multiplexed data interface 22 includes a switch 71, an LDO 74, a control unit 75, a PLL 77, a transmission processing unit 78, a switch 80, microphones 81 0 to 81 4 , amplifiers 82 0 to 82 4 , It comprises resistors 83 0 to 83 4 , ADCs 84 0 to 84 4 , nonvolatile memory 85, power detection unit 111, and authentication pattern output unit 112.
- the plug detection unit 101 monitors the signal on the detection line connected to the jack 14, and the plug is inserted into the jack 14 based on the signal on the detection line. Is detected.
- the jack 14 is provided with, for example, a mechanical mechanism for detecting insertion of the plug, and the detection line is connected to the mechanical mechanism.
- a signal on the detection line is changed. Based on the above signal, it is detected that a plug is inserted into the jack 14.
- the switch 41 that selects the terminal 41A by default is switched to select the terminal 41B.
- the authentication pattern output unit 102 stores an authentication pattern as a predetermined signal for authenticating (detecting) that the host device 10 is a compatible device, and outputs the authentication pattern to the transmission / reception processing unit 47.
- the transmission / reception processing unit 47 outputs the authentication pattern for a predetermined time.
- the authentication pattern from the unit 102 is transmitted.
- the authentication pattern transmitted by the transmission / reception processor 47 is output from the microphone terminal TJ3 of the jack 14 via the multiplexed data signal line JB and the switch 41 selecting the terminal 41B.
- the authentication pattern stored in the authentication pattern output unit 102 is also referred to as a master authentication pattern hereinafter.
- the pattern detection unit 103 is connected to the multiplexed data signal line JB connected to the terminal 41B of the switch 41. From the input device 20 that is a corresponding device, the pattern detection unit 103 selects the microphone terminal TJ3 (The authentication pattern (slave authentication pattern described later) transmitted via the switch 41 and the multiplexed data signal line JB is received.
- the authentication pattern (slave authentication pattern described later) transmitted via the switch 41 and the multiplexed data signal line JB is received.
- the pattern detection unit 103 detects that the plug device having the plug inserted into the jack 14 is a compatible device by receiving the slave authentication pattern.
- the pattern detection unit 103 supplies to the interrupter 46 that the switch 41 has been switched to select the terminal 41B. .
- the pattern detection unit 103 detects that the plug is inserted into the jack 14 in the plug detection unit 101 and switches the switch 41 to select the terminal 41B. If the authentication pattern cannot be received, it is detected that the plug device having the plug inserted into the jack 14 is not a compatible device, and the switch 41 switched to select the terminal 41B is connected to the terminal 41B. Switch again to select 41A.
- the power detection unit 111 detects that the plug 23 is inserted into the jack by detecting a change in the voltage of the microphone terminal TP3 of the plug 23.
- the plug 23 when the plug 23 is inserted into the jack 14 of the host device 10 (in addition, for example, when the plug 23 is inserted into the jack of an existing jack device corresponding to an existing headset with four poles having a microphone) )
- the resistor 33, the switch for selecting the terminal 41A, and the microphone terminal TJ3 of the jack 14 or the multiplexed data signal line JB and the terminal 41B are selected. are switches 41 and, via the microphone terminal TJ3 of the jack 14, appears the voltage of the power supply V D is.
- the power detection unit 111 detects that the plug 23 is inserted into the jack, and selects the terminal 71A by default.
- the switch 71 is switched to select the terminal 71B.
- the authentication pattern output unit 112 stores an authentication pattern as a predetermined signal for authenticating (detecting) that the input device 20 is a compatible device, and outputs the authentication pattern to the transmission processing unit 78.
- the authentication pattern stored in the authentication pattern output unit 112 is hereinafter also referred to as a slave authentication pattern.
- the control unit 75 has the jack into which the plug 23 is inserted.
- the master device receives the master authentication pattern from the jack device via the microphone terminal TP3 of the plug 23, the switch 71 selecting the terminal 71B, and the multiplexed data signal line PB.
- control unit 75 When the control unit 75 receives the master authentication pattern, the control unit 75 detects that the jack device having the jack into which the plug 23 is inserted is a compatible device, and sends a slave authentication pattern from the authentication pattern output unit 112 to the transmission processing unit 78. , For a predetermined time.
- the slave authentication pattern transmitted by the transmission processing unit 78 is output from the microphone terminal TP3 of the plug 23 via the multiplexed data signal line JB and the switch 71 selecting the terminal 71B.
- control unit 75 detects the master authentication pattern at a predetermined time after the power detection unit 111 detects that the plug 23 is inserted into the jack and the switch 71 is switched to select the terminal 71B.
- the switch 71 switched to select the terminal 71B is selected, and the terminal 71A is selected. Switch again.
- FIG. 9 is a flowchart for explaining processing of the host device 10 and the input device 20 of FIG.
- step S41 the switch 41 selects the terminal 41A by default.
- step S51 the switch 71 selects the terminal 71A by default.
- the plug detection unit 101 detects that the plug is inserted into the jack 14 in step S 42.
- the switch 41 that selects the terminal 41A by default is switched to select the terminal 41B in step S43.
- step S44 the transmission / reception processing unit 47 starts transmission of the clock (including the signal) in synchronization with the clock from the clock generation unit 15.
- step S44 the transmission / reception processing unit 47 starts transmitting the master authentication pattern stored in the authentication pattern output unit 102 in synchronization with the clock from the clock generation unit 15.
- the clock and master authentication pattern transmitted by the transmission / reception processing unit 47 are output from the microphone terminal TJ3 of the jack via the multiplexed data signal line JB and the switch 41.
- step S45 the pattern detection unit 103 waits for the slave authentication pattern to be transmitted from the plug device having the plug inserted into the jack 14.
- the pattern detection unit 103 confirms that the plug device having the plug inserted into the jack 14 is not a compatible device in step S46.
- the switch 41 that has been detected (recognized) and switched to select the terminal 41B is switched again to select the terminal 41A.
- the host device 10 is connected to the plug device having the plug inserted into the jack 14 as described with reference to FIG.
- the operation (conventional mode operation) when the device is not a compatible device, such as an existing headset with 4 poles, is performed.
- step S47 unit 103 receives the slave authentication pattern.
- the pattern detection unit 103 detects that the plug device having the plug inserted into the jack 14 is a compatible device by receiving the slave authentication pattern.
- the pattern detection unit 103 supplies to the interrupter 46 that the switch 41 has been switched to select the terminal 41B. .
- the signal processing block When the interrupter 46 is supplied from the pattern detection unit 103 that the switch 41 has been switched to select the terminal 41B, the signal processing block indicates that the corresponding device (plug) has been inserted into the jack 14. 11 is supplied.
- the transmission / reception processing unit 47 transmits an ACK (ACKnowledgement) (acknowledgement) signal to the multiplexed data signal line JB, the switch 41, and the microphone of the jack 14 in step S48. It transmits (replies) to the input device 20 as a plug device having a plug inserted into the jack 14 via the terminal TJ3.
- ACK acknowledgeledgement
- acknowledgement acknowledgement
- step S49 the transmission / reception processing unit 47 performs multiplexing transmitted from the input device 20 via the microphone terminal TJ3 of the jack 14, the switch 41, and the multiplexed data signal line JB as described later. Start receiving data.
- the power detection unit 111 detects that the plug 23 is inserted into the jack in step S52. .
- the microphone 33 TP3 of the plug 23 has a resistor 33, a switch for selecting the terminal 41A, and the microphone terminal of the jack 14. via TJ3, or multiplexed data signal lines JB, switch 41 selects the terminal 41B, and, through a microphone terminal TJ3 of the jack 14, appears a voltage of the power supply V D.
- Power detector 111 the voltage of the microphone terminal TP3 of the plug 23, by changing the voltage of the power supply or the like V D, detects that the plug 23 is inserted into the jack.
- the power detection unit 111 When detecting that the plug 23 has been inserted into the jack, the power detection unit 111 switches the switch 71 that selects the terminal 71A by default to select the terminal 71B in step S53.
- the switch 71 When the switch 71 is switched to select the terminal 71B, the microphone terminal TP3 of the plug 23 is connected to the LDO 74 via the switch 71 (selecting the terminal 71B).
- the microphone terminal TP3 of the plug 23 is connected to the control unit 75, the PLL 77, and the transmission processing unit 78 via the switch 71 and the multiplexed data signal line PB.
- step S43 the switch 41 is switched to select the terminal 41B.
- the microphone terminal TJ3 of the jack 14 selects (the terminal 41B is selected). and are) switch 41 and, via a multiplexed data signal lines JB, transmission and reception processing unit 47, pattern detection unit 103 and are connected to a power supply V D.
- the microphone terminal TJ3 of the jack 14 is connected to the power source V D via the switch 41 and the multiplexed data signal line JB, so that the power source V D is the multiplexed data of the host device 10.
- the signal line JB, the switch 41, the microphone terminal TJ3 of the jack 14, and the microphone 71 TP3 of the plug 23 of the input device 20 and the switch 71 that selects the terminal 71B are connected to the LDO 74. .
- the LDO 74 supplies power to the block that requires power such as the amplifier 82 i of the input device 20 to the power source. Start supplying.
- step S44 the transmission / reception processing unit 47 starts transmission of the clock and the master authentication pattern, and the clock and the master authentication pattern are multiplexed data signal lines.
- the signal is output from the microphone terminal TJ3 of the jack 14 via JB and the switch 41.
- the clock output from the microphone terminal TJ3 of the jack 14 and transmitted by the transmission / reception processing unit 47 is input to the PLL 77 via the microphone terminal TP3 of the plug 23, the switch 71, and the multiplexed data signal line PB. To be supplied.
- step S54 the PLL 77 starts to operate in accordance with the clock from the transmission / reception processing unit 47 supplied as described above.
- the PLL 77 enters a so-called locked state, a clock synchronized with the clock from the transmission / reception processing unit 47 is transmitted to the transmission processing unit. 78 etc.
- the transmission processing unit 78 starts operation in synchronization with the clock from the PLL 77.
- the control unit 75 waits for the master authentication pattern to be transmitted from the host device 10 in step S55. Receive.
- the transmission / reception processing unit 47 starts transmitting the master authentication pattern, and the master authentication pattern is transmitted to the jack 14 via the multiplexed data signal line JB and the switch 41. Output from microphone terminal TJ3.
- the control unit 75 receives the master authentication pattern output from the microphone terminal TJ3 of the jack 14 via the microphone terminal TP3 of the plug 23, the switch 71, and the multiplexed data signal line PB.
- the jack device having the jack in which the plug 23 is inserted If the clock is not supplied to the PLL 77 in step S54, or if the master authentication pattern cannot be received by the control unit 75 in step S55, the jack device having the jack in which the plug 23 is inserted. However, the switch 71 that has been switched to select the terminal 71B on the assumption that it is not a compatible device is switched again to select the terminal 71A.
- the input device 20 is a jack device having a jack into which the plug 23 is inserted as described with reference to FIG. Operation is performed when the device is not a compatible device, such as an existing smartphone that supports an existing headset with 4 poles.
- the control unit 75 When receiving the master authentication pattern in step S55, the control unit 75 detects that the jack device having the jack into which the plug 23 is inserted is a compatible device, and outputs the authentication pattern to the transmission processing unit 78 in step S56.
- the slave authentication pattern from the unit 112 is transmitted for a predetermined time.
- the slave authentication pattern transmitted by the transmission processing unit 78 is output from the microphone terminal TP3 of the plug 23 via the multiplexed data signal line JB and the switch 71 selecting the terminal 71B.
- the slave authentication pattern output from the microphone terminal TP3 of the plug 23 includes the pattern detection unit 103 via the microphone terminal TJ3 of the jack 14, the switch 41 (the terminal 41 is selected), and the multiplexed data signal line JB. And is received by the pattern detection unit 103 in step S47 as described above.
- the transmission / reception processing unit 47 converts the ACK signal to the multiplexed data signal line JB, the switch 41, and the jack in step S48 as described above.
- the ACK signal transmitted via the microphone terminal TJ3 of the jack 14 is transmitted to the control unit 75 or the PLL 77 of the input device 20 as described above.
- the signal is received via the microphone terminal TP3, the switch 71, and the multiplexed data signal line PB.
- the transmission processing unit 78 at step S57, the switch signal from the switch 80, the digital sound signal #i, data read from the register 76 from the ADC 84 i, and read from the nonvolatile memory 85
- the multiplexed data obtained as a result of multiplexing the multiplexed data signal line PB, the switch 71, the microphone terminal TP3 of the plug 23, the microphone terminal TJ3 of the jack 14, the switch 41, and the multiplexed data signal line JB. Then, the process of transmitting to the transmission / reception processing unit 47 is started.
- step S49 the multiplexed data transmitted from the transmission processing unit 78 as described above is transmitted via the microphone terminal TJ3 of the jack 14, the switch 41, and the multiplexed data signal line JB. Received by the transmission / reception processing unit 47.
- the plug 23 is inserted into the jack in response to a predetermined change in the current, not the voltage at the microphone terminal TP3 of the plug 23. Can be detected.
- the selection of the terminal 71A can be maintained as it is without switching the switch 71 that selects the terminal 71A by default, thereby enabling the following operation.
- the microphone terminal TP3 of the plug 23 is connected via the resistor 33 in addition to the microphone terminal TJ3 of the jack 14 and the switch 41. Connected to power supply V D. Voltage in this case, the microphone terminal TP3 of the plug 23, the voltage of the power supply V D, becomes a voltage dropped by the voltage drop at the resistor 33, so does not reach the voltage of the power source V D, power detection unit 111, The selection of the terminal 71A is maintained without switching the switch 71 that selects the terminal 71A.
- the switch 41 of the host device 10 selects the terminal 41B
- the microphone terminal TP3 of the plug 23 is connected to the power source V D via the microphone terminal TJ3 of the jack 14 and the switch 41.
- the voltage of the microphone terminal TP3 of the plug 23 becomes the voltage of the power source V D.
- the power detection unit 111 switches the switch 71 selecting the terminal 71A so as to select the terminal 71B.
- the switch 71 selects the terminal 71A by default, the terminal 71B In the host device 10, the switch 41 selects the terminal 41 ⁇ / b> B, and the master authentication pattern is transmitted from the transmission / reception processing unit 47 via the multiplexed data signal line JB and the switch 41. Only when the signal is output from the terminal TJ3 of the jack 14, the switch 71 is switched from the terminal 71A to the terminal 71B.
- the input device 20 has the switch 71 in the power detection unit 111. Since the terminal 71A is switched to the terminal 71B, the control unit 75 of the input device 20 can receive the master authentication pattern from the host device 10 after the switch 71 is switched to the terminal 71B.
- the switch 71 when the host device 10 and the input device 20 are connected, when the switch 71 is switched to select the terminal 71B in the input device 20, the master authentication pattern from the host device 10 is switched after the switching. Can be received. Therefore, as described with reference to FIGS. 8 and 9, in the input device 20, the situation in which the master authentication pattern cannot be received within a predetermined time after the switch 71 is switched to select the terminal 71B is as follows. Therefore, the switch 71 that has been switched to select the terminal 71B is switched again to select the terminal 71A according to such a situation.
- FIG. 10 is a block diagram illustrating a seventh detailed configuration example of the host device 10 and the input device 20.
- the host device 10 is common to the case of FIG. 7 in that it includes a signal processing block 11, a clock generation unit 15, a DAC 31, a power amplifier 32, a register 48, and an I 2 C interface 49.
- the host device 10 is provided with a reception processing unit 122 instead of the transmission / reception processing unit 47 and a PLL 121 and a SRC (Sampling Rate Converter) 123 are newly provided. This is different from the case of FIG.
- the analog acoustic interface 12 includes a DAC 31 and a power amplifier 32 (similar to the case of FIG. 7).
- the multiplexed data interface 13 includes a register 48, an I 2 C interface 49, a PLL 121, a reception processing unit 122, and an SRC 123.
- the input device 20 includes drivers 61L and 61R, an LDO 74, a control unit 75, a transmission processing unit 78, a switch 80, microphones 81 0 to 81 4 , amplifiers 82 0 to 82 4 , resistors 83 0 to 83 4. , ADCs 84 0 to 84 4 and the nonvolatile memory 85 are common to the case of FIG.
- the input device 20 is different from the case of FIG. 7 in that a clock generation unit 132 is provided instead of the PLL 77 and a synchronization unit 131 is newly provided.
- the analog acoustic interface 21 includes drivers 61L and 61R (similar to the case shown in FIG. 7).
- the multiplexed data interface 22 includes an LDO 74, a control unit 75, a transmission processing unit 78, a switch 80, microphones 81 0 to 81 4 , amplifiers 82 0 to 82 4 , resistors 83 0 to 83. 4 , ADCs 84 0 to 84 4 , a nonvolatile memory 85, a synchronization unit 131, and a clock generation unit 132.
- the PLL 121 synchronizes with the signal from the signal (multiplexed data) transmitted from the input device 20 via the microphone terminal TJ3 of the jack 14 onto the multiplexed data signal line JB.
- the generated clock is generated and supplied to the reception processing unit 122.
- the reception processing unit 122 operates in synchronization with the clock from the PLL 121 and, like the transmission / reception processing unit 47 of FIG. 7 (FIG. 2), from the input device 20, the microphone terminal TJ3 of the jack 14, the switch 41, and the multiplexing The multiplexed data supplied via the multiplexed data signal line JB is received.
- the reception processing unit 122 performs an appropriate process on the multiplexed data such as demultiplexing the multiplexed data, and is included in the multiplexed data.
- Digital acoustic signals # 0, # 1, # 2, # 3, # 4 and additional data as original data are separated and supplied to the SRC 123.
- the SRC 123 operates in synchronization with a clock (hereinafter also referred to as a host clock) supplied from the clock generation unit 15, and the digital acoustic signals # 0, # 1, # 2, # 3, # from the reception processing unit 122 are operated. 4 and the additional data are converted into data synchronized with the clock from the clock generator 15 and supplied to the signal processing block 11.
- a clock hereinafter also referred to as a host clock
- the reception processing unit 122 operates in synchronization with the clock from the PLL 121, and the clock from the PLL 121 has a clock synchronized with a signal transmitted from the input device 20, that is, the input device 20 has, which will be described later.
- This clock is synchronized with a clock (hereinafter also referred to as a device clock) generated by the clock generator 132.
- the digital acoustic signals # 0, # 1, # 2, # 3, # 4 and additional data obtained by the reception processing unit 122 are data synchronized with the device clock on the input device 20 side.
- the acoustic signal # 0, # 1, # 2, # 3, # 4 and additional data synchronized with the device clock on the input device 20 side and the additional data are generated by the clock generation unit 15, and the host device 10 It is converted to data synchronized with the master clock on the side.
- the clock generation unit 132 generates a device clock and supplies it to the transmission processing unit 78.
- the transmission processing unit 78 operates in synchronization with the device clock generated by the clock generation unit 132, not the clock generated by the PLL 77 and synchronized with the master clock, as shown in FIG. 7 (FIG. 2). To do.
- the multiplexed data transmitted by the transmission processing unit 78 is data synchronized with the device clock.
- the synchronization unit 131 delimits the multiplexed data obtained by the transmission processing unit 78, that is, digital audio signals # 0, # 1, # 2, # 3, # 4 included in the multiplexed data, and additional data
- a synchronization signal representing a break of a group (for example, a frame described later) is generated and supplied to the transmission processing unit 78.
- the synchronization signal from the synchronization unit 131 is included at the position where the multiplexed data is delimited.
- the reception processing unit 122 of the host device 10 uses the synchronization signal included in the multiplexed data as a reference, so that the acoustic signals # 0, # 1, # 2, # 3, # 4, and additional data are stored. To be separated.
- the host device 10 and the input device 20 configured as described above operate asynchronously.
- the host device 10 when the host device 10 and the input device 20 are connected, the host device 10 operates in synchronization with the master clock generated by the clock generation unit 15, Since the input device 20 operates in synchronization with a clock that is synchronized with the master clock generated by the PLL 77 (FIG. 7 and the like), the host device 10 and the input device 20 operate in synchronization.
- the host device 10 operates in synchronization with the master clock generated by the clock generation unit 15, and the input device 20 operates in synchronization with the device clock generated by the clock generation unit 132. Therefore, the host device 10 and the input device 20 operate asynchronously.
- the power source V D of the host device 10 and the LDO 74 of the input device 20 are connected to the multiplexed data signal line JB, the microphone terminal TJ3 of the jack 14, The plug 23 is connected via the microphone terminal TP3 and the multiplexed data signal line PB.
- the LDO 74 starts supplying power to be a power source to a block that requires a power source such as the amplifier 82 i of the input device 20.
- the transmission processing unit 78 starts transmitting multiplexed data.
- the transmission processing unit 78 operates synchronously with the device clock by the clock generator 132 generates the synchronization signal supplied from the synchronization section 131, to the acoustic signal # 0 of the digital supplied from ADC 84 0 to 84 4
- Multiplex data including additional data such as # 4 and device information stored in the non-volatile memory 85 and a switch signal output from the switch 80 is generated and transmitted.
- the multiplexed data transmitted by the transmission processing unit 78 includes the PLL 121 and the reception via the multiplexed data signal line PB, the microphone terminal TP3 of the plug 23, the microphone terminal TJ3 of the jack 14, and the multiplexed data signal line JB. It is supplied to the processing unit 122.
- the PLL 121 receives the multiplexed data from the transmission processing unit 78, generates a clock synchronized with the multiplexed data, and supplies it to the reception processing unit 122.
- the reception processing unit 122 operates in synchronization with the clock from the PLL 121 and receives multiplexed data from the transmission processing unit 78. Then, the reception processing unit 122 separates the digital acoustic signals # 0, # 1, # 2, # 3, # 4 and additional data included in the multiplexed data and supplies them to the SRC 123.
- the SRC 123 operates in synchronization with the host clock supplied from the clock generation unit 15, and receives the digital acoustic signals # 0, # 1, # 2, # 3, # 4 and additional data from the reception processing unit 122.
- the data is converted into data synchronized with the clock from the clock generation unit 15 and supplied to the signal processing block 11.
- the host device 10 and the input device 20 that operate asynchronously in FIG. 10 do not have backward compatibility, similar to the host device 10 and the input device 20 in FIG.
- the host device 10 and the input device 20 that operate asynchronously can be configured to have backward compatibility like the host device 10 and the input device 20 of FIG.
- the backward compatible host device 10 and the input device 20 of FIG. 2 can be configured to operate asynchronously as described in FIG.
- a signal exchanged between the host device 10 and the input device 20 in the sixth detailed configuration example in FIG. 8 is taken as an example.
- the signal format will be described.
- a signal transmitted from the host device 10 to the input device 20 in FIG. 8 for example, there are a master authentication pattern (Authentication signal) and a command transmitted by the transmission / reception processing unit 47.
- Authentication signal a master authentication pattern
- command transmitted by the transmission / reception processing unit 47 a command transmitted by the transmission / reception processing unit 47.
- examples of the signal transmitted from the input device 20 to the host device 10 in FIG. 8 include a slave authentication pattern (Authentication signal) transmitted from the transmission processing unit 78, multiplexed data, and the like.
- examples of commands transmitted from the host device 10 to the input device 20 include a read command for requesting data reading and a write command for requesting data writing.
- the command consists of an opcode and required operands.
- the read command has a code representing data reading as an operation code, and the head address (head address) of the address from which data is read and the number of addresses from which the data is read from the head address (data for several addresses) Read) as an operand.
- the write command has a code representing data writing as an operation code, and has a write address for writing data and data to be written to the write address (write data) as operands.
- the control unit 75 performs a process according to the stored value of the built-in register 76, so that the host device 10 rewrites the stored value of the register 76 by a write command.
- Various processes for example, switching on / off of the ADC 84 i , switching of the operation mode between the standby (power saving) mode and the normal mode of the LDO 74, and other processing) are performed on the input device 20 (the control unit 75). Can be performed.
- the host device 10 can read device information from the nonvolatile memory 85 of the input device 20 by a read command.
- the multiplexed data transmitted from the input device 20 to the host device 10 includes, for example, digital acoustic signals # 0, # 1, # 2, # 3, # 4 and additional data as described above. included.
- the multiplexed data includes acoustic signals # 0, # 1, # 2, # 3, and # 4 of 5 channels at the maximum. Further, the multiplexed data includes additional data.
- the additional data can include (adopt) a switch signal and device information. Further, the additional data can include (adopt) the data read by the input device 20 in response to the read command from the host device 10, the address where the data is stored, and the like.
- the switch signal included in the additional data is the switch signal of the switch 80.
- the additional data can include, for example, a maximum of four switch signals.
- FIG. 11 is a timing chart showing an example of signals exchanged between the host device 10 and the input device 20 from when the plug 23 is inserted into the jack 14 until transmission / reception of multiplexed data becomes possible. .
- FIG. 11A shows a clock transmitted from the host device 10 to the input device 20.
- a pulse signal having a frequency of about 12 to 15 MHz can be employed.
- the host device 10 starts clock transmission in step S44, but the clock transmission is continued for a predetermined time such as 10 ms, for example.
- the clock transmitted from the host device 10 to the input device 20 is a pulse in which the periods of the H level and the L level are equal, and the individual periods of the H level and the L level are also referred to as slots hereinafter. Further, hereinafter, the H level is represented by “1” and the L level is represented by “0” as appropriate. In this case, the clock is represented by “10101010...”.
- FIG. 11B shows a master authentication pattern that the host device 10 transmits to the input device 20.
- the master authentication pattern can be, for example, a one-frame pattern “1011100010”.
- the host device 10 starts transmitting the master authentication pattern in step S44, and the transmission of the master authentication pattern is continuously repeated for a predetermined time such as 5 ms, for example.
- 11C shows an ACK signal transmitted from the host device 10 to the input device 20.
- the 2-slot pattern “10” can be used as the ACK signal.
- the 2-slot pattern “10” as the ACK signal is arranged at the end of the frame, and is set to high impedance (Hi-Z) during the other 8 slots (the jack 14 of the host device 10 as viewed from the outside).
- the impedance of the microphone terminal TJ3 is set to high impedance).
- the host device 10 transmits an ACK signal in step S48, and the transmission of the ACK signal is repeatedly continued for a predetermined time such as 5 ms, for example.
- the input device 20 uses the clock of A in FIG. 11 to synchronize the PLL 77 (after locking the PLL 77), and then uses the 2-slot pattern “10” as the ACK signal to generate the PLL 77. Synchronization is maintained.
- 11D shows a slave authentication pattern transmitted from the input device 20 to the host device 10.
- the slave authentication pattern is an 8-slot pattern “11100010”, which is placed at the beginning of the frame and is set to high impedance for the other two-slot periods (the microphone terminal of the plug 23 of the input device 20 as viewed from the outside).
- TP3 impedance is set to high impedance).
- the input device 20 transmits a slave authentication pattern in step S56, and the transmission of the slave authentication pattern is continuously repeated for a predetermined time such as 5 ms, for example.
- the slave authentication pattern is transmitted from the input device 20 to the host device 10 in a period other than the first 8 slots of one frame, that is, in the last two slots of one frame, the host device 10 inputs the input device 20.
- a signal (for example, the ACK signal in FIG. 11C) is transmitted to the input device 20, and the signal transmitted from the host device 10 during the last two slots for one frame is transmitted as necessary.
- PLL 77 synchronization is maintained.
- FIG. 12 is a timing chart showing an example of signals exchanged between the host device 10 and the input device 20 after the multiplexed data can be transmitted and received.
- FIG. 12B shows a frame synchronization signal indicating the head of the frame.
- the frame synchronization signal is a pulse signal, and the rising edge represents the timing of the beginning of the frame.
- the frame synchronization signal is, for example, a pulse signal having a frequency of about 1.2 MHz.
- FIG. 12C shows the signal transmission timing and reception timing of the host device (hereinafter also referred to as master) 10.
- the host device 10 transmits a signal to the input device 20 in the last two slots of the frame, and receives a signal transmitted from the input device 20 in the first eight slots of the frame.
- D in FIG. 12 shows the signal transmission timing and the reception timing of the input device (hereinafter also referred to as a slave) 20.
- a signal is transmitted to the host device 10 in the first 8 slots of the frame, and a signal transmitted from the host device 10 is received in the last 2 slots of the frame.
- FIG. 12E shows a signal transmitted by the host device 10.
- the host device 10 transmits an ACK / R signal in the last two slots of the frame.
- the ACK / R signal is a 2-slot pattern “10” or “01”, and the input device 20 maintains the synchronization of the PLL 77 using the ACK / R signal. Note that it is not always necessary to use the ACK / R signal of each frame in order to maintain the PLL 77 synchronization.
- the synchronization of the PLL 77 can be maintained using an ACK / R signal of every other frame, for example.
- Fig. 12F shows multiplexed data transmitted by the input device 20.
- the input device 20 transmits multiplexed data in the first 8 slots of the frame.
- the multiplexed data of one frame is an 8-slot pattern, that is, 8-bit data, but in FIG. 12, as 8-bit data as the multiplexed data of one frame, for DC free, for example, 8-bit data obtained by converting 6-bit real data to 6B / 8B (6bit / 8bit) is adopted.
- the additional data of the super frame is N-bit data, but in this embodiment, N bits as additional data of the super frame are used.
- a position (frame) in which a switch signal as additional data, device information, and other data are arranged is assigned in advance to this data.
- the additional data is transmitted in units of superframes.
- 8-bit data obtained by 6B / 8B conversion of 6-bit actual data is adopted as 8-bit data as multiplexed data of one frame for DC-free.
- 8-bit actual data is used as it is as 8-bit data as 1-frame multiplexed data. be able to.
- conversion performed for DC-free is not limited to 6B / 8B conversion.
- the data included in 1-frame multiplexed data is not limited to 1-bit audio signal of 5 channels or 1-bit additional data.
- a 1-bit acoustic signal having more than 5 channels additional data of multiple bits, or the like can be employed.
- one frame of multiplexed data exceeds 8 bits, for example, by increasing the speed of the clock, etc., by configuring one frame with the required number of slots exceeding 10 slots.
- data exceeding 8 bits can be used.
- FIG. 13 is a timing chart showing an example of a signal as a command transmitted from the host device 10 to the input device 20.
- FIG. 13A shows the same frame synchronization signal as B in FIG.
- the scale of the time axis (lateral direction) is smaller (coarse) than B in FIG.
- FIG. 13B shows a read command
- the host device 10 transmits one read command using an ACK / R signal of 21 frames (E in FIG. 12).
- the first two ACK / R signals constitute the read command opcode, and the remaining 19 ACK / R signals constitute the read command operand. ing.
- the ACK / R signal of one frame is a 2-slot pattern “10” or “01”.
- the 2 bits “10” as the opcode of the read command are represented by the 4-slot pattern “10” and “01” as the 2-frame ACK / R signal.
- a 10-bit read address (start address) and a 9-bit read address (register) number are adopted.
- the 10-bit read address as the operand of the read command is used as the head address, and the data of the number of addresses represented by the number of 9-bit read addresses as the operand of the read command from the head address. Are read out and included in the additional data, for example, and transmitted to the host device 10.
- FIG. 13C shows a write command
- the host device 10 transmits one write command using the 21-frame ACK / R signal (E in FIG. 12) similar to the read command in FIG. 13B. .
- the first two ACK / R signals constitute the write command opcode, and the remaining 19 ACK / R signals constitute the write command operand. ing.
- a 10-bit write address As the write command operand, a 10-bit write address, a fixed 1-bit "0”, and an 8-bit write data are used.
- 8-bit write data as the write command operand is written to the 10-bit write address as the write command operand.
- the storage area of one address in the address space of the input device 20 (the storage area represented by one address) is an 8-bit storage area.
- the host device 10 and the input device 20 can be applied to, for example, a system that performs NR (Noise Reduction), a system that performs beam forming, and a system that performs various other signal processing.
- NR Noise Reduction
- NR includes NC (Noise Cancel) and noise suppression.
- NC is a technology for obtaining sound (sound waves) from which noise is removed (reduced) by applying (adding) noise to the sound emitted from the driver into the real space (in the air). means.
- noise suppression means a technique for obtaining an acoustic signal from which noise has been removed by performing signal processing on the acoustic signal.
- NC and noise suppression are common in that noise is removed, but in NC, noise is removed in real space, whereas in noise suppression, noise removal is signal processing.
- noise suppression is signal processing.
- NC and noise suppression will be described as preparations before that.
- NC includes, for example, FB (feedback) method, FF (feed forward) method, and FF + FB method.
- FIG. 14 is a block diagram illustrating a configuration example of an FB-type NC system that performs FB-type NC.
- a listener (user) 1011 wears headphones, and the right ear of the listener 1011 is covered by a right-ear headphone housing (housing) 1012.
- FIG. 14 for the sake of simplicity of explanation, the configuration of only the right ear side portion of the headphone listener 11 is shown, but the left ear side portion is configured similarly. The same applies to an FF NC system that performs FF NC described later, and an FF + FB NC system that performs FF + FB NC.
- a driver (headphone driver) 1013 is provided as an electro-acoustic conversion means for acoustically reproducing an acoustic signal that is an electric signal.
- a music (sound) signal is supplied from the acoustic signal input terminal 1014 to the power amplifier 1017 through the equalizer 1015 and the addition circuit 1016.
- the power amplifier 1017 amplifies the music signal supplied thereto and supplies it to the driver 1013, and the driver 1013 outputs the corresponding sound.
- the playback sound of the music signal is perceived by the right ear of the listener 1011.
- the acoustic signal input terminal 1014 is composed of, for example, a headphone plug inserted into a headphone jack of a music player (not shown).
- an equalizer 1015, an adder circuit 1016, and a power amplifier 1017 are provided in an acoustic signal transmission path between the acoustic signal input terminal 1014 and the driver 1013.
- a microphone 14 further includes a microphone 1021, a microphone amplifier 1022, and an FB filter circuit 1023 as acoustic-electric conversion means.
- the listener 1011 in the music listening environment of the listener 1011, noise that enters a later-described cancel point Pc of the listener 1011 in the headphone housing 1012 from the noise source 1018 outside the headphone housing 1012 is reduced. To do. Thereby, the listener 1011 can listen to music in a favorable environment.
- the noise at the cancellation point Pc in which the listener 1011 is simulated as the auditory position for perceiving sound (sound waves) and the sound reproduction sound output from the driver 1013 is combined.
- the sound is picked up by the microphone 1021.
- the microphone 1021 is provided at the cancellation point Pc inside the headphone housing (housing) 1012 as a noise collecting microphone.
- the cancellation point Pc for example, a position on the front surface of the diaphragm of the driver 1013 is employed, which is a position close to the ear, and the microphone 1021 is provided at such a cancellation point Pc (close position).
- a negative phase component of the noise picked up by the microphone 1021 is generated as an NC acoustic signal, and the NC acoustic signal is supplied to the driver 11 for sound reproduction, so that headphones are externally supplied. Noise that enters the housing 1012 is reduced.
- noise in the noise source 1018 and the noise 1018 ′ entering the headphone housing 1012 are not the same characteristics.
- noise 1018 ′ entering the headphone housing 1012 that is, noise 1018 ′ to be reduced is collected by the microphone 1021.
- a reverse phase component of the noise 1018 ′ is generated so as to cancel the noise 1018 ′ collected at the cancellation point Pc by the microphone 1021.
- the FB filter circuit 1023 is used to generate an NC acoustic signal as an antiphase component of the noise 1018 '.
- the FB filter circuit 1023 includes an FB filter operation unit 1232, an ADC 1231 provided in the preceding stage, and a DAC 1233 provided in the subsequent stage.
- the obtained analog acoustic signal picked up by the microphone 1021 is supplied to the FB filter circuit 1023 through the microphone amplifier 1022 and AD-converted into a digital acoustic signal by the ADC 1231. Then, the digital acoustic signal is supplied to the FB filter arithmetic unit 1232.
- the FB filter operation unit 1232 is configured by, for example, a DSP (Digital Signal Processor) or the like, and performs an operation as a digital filter (hereinafter also referred to as FB filter operation) for generating an FB digital NC acoustic signal.
- the digital filter generates a digital NC sound signal having characteristics according to a filter coefficient as a parameter set in the digital sound signal input thereto.
- a predetermined filter coefficient is set in the digital filter of the FB filter calculation unit 1232.
- the digital NC acoustic signal generated by the FB filter arithmetic unit 1232 is DA-converted into an analog NC acoustic signal by the DAC 1233.
- the analog NC acoustic signal is supplied to the adder circuit 1016 as an output signal of the FB filter circuit 1023.
- the addition circuit 1016 is supplied with an input sound signal (music signal or the like) S intended to be listened to by the listener 1011 through headphones via the sound signal input terminal 1014 and the equalizer 1015.
- the equalizer 1015 performs sound quality correction by changing the frequency characteristics of the input acoustic signal.
- the addition circuit 1016 adds the input acoustic signal from the equalizer 1015 and the NC acoustic signal as the output signal of the FB filter circuit 1023.
- the acoustic signal resulting from the addition by the addition circuit 1016 is supplied to the driver 1013 through the power amplifier 1017 and reproduced.
- the sound that is reproduced and emitted by the driver 1013 includes an acoustic reproduction component by the NC acoustic signal generated in the FB filter circuit 1023.
- the sound reproduction component by the sound signal for NC and the noise 1018 ′ are acoustically synthesized, so that the noise 1018 ′ is reduced (cancelled) at the cancellation point Pc. )
- FIG. 15 is a diagram for explaining a transfer function of the NC system of the FB method in FIG.
- A is the transfer function of the power amplifier 1017
- D is the transfer function of the driver 1013
- M is the transfer function corresponding to the microphone 1021 and microphone amplifier 1022 parts.
- - ⁇ is the transfer function of the FB filter circuit 1023
- H is the transfer function of the space from the driver 1013 to the cancellation point (auditory position) Pc (and hence the microphone 1021)
- E is the transfer function of the equalizer 1015, Each will be represented.
- N is the noise that has entered the vicinity of the microphone 1021 position in the headphone housing 1012 from the external noise source 1018
- P is the sound that the listener 1011 listens to with the sound pressure that reaches the ear of the listener 1011.
- the case where external noise is transmitted into the headphone housing 1012 includes, for example, the case where sound pressure leaks from the gap between the ear pad portions of the headphones, or the result of the headphone housing 1012 receiving vibration and vibrating. In some cases, sound is transmitted to the inside of the headphone housing 1012.
- Formula (3) Formula (1) will be represented by Formula (3).
- the noise N is attenuated to 1 / (1 + ADHM ⁇ ).
- the listener 1011 can listen to the sound to be listened to with reduced noise.
- the digital filter as the FB filter calculation unit 1232 has a characteristic of the noise 1018 ′ transmitted into the headphone housing 1012.
- the corresponding filter coefficient needs to be set. That is, the filter coefficient of the FB filter calculation unit 1232 is, for example, the characteristics of the microphone 1021 and the microphone amplifier 1022 so that the noise N included in the listening sound P represented by Expression (3) can be appropriately reduced. Is set based on the transfer function M as a driver, the transfer function D as a characteristic of the driver 1013, and the like.
- FIG. 16 is a block diagram illustrating a configuration example of an FF-type NC system that performs FF-type NC.
- FIG. 16 portions corresponding to those in FIG. 14 are denoted by the same reference numerals, and description thereof will be omitted below as appropriate.
- the listener 1011 in the music listening environment of the listener 1011, noise that enters the cancellation point Pc of the listener 1011 in the headphone housing 1012 from the noise source 1018 outside the headphone housing 1012 is reduced. The Thereby, the listener 1011 can listen to music in a favorable environment.
- a microphone 1031 is installed outside the headphone housing 1012.
- the noise 1018 picked up by the microphone 1031 is appropriately filtered to generate an NC acoustic signal.
- the generated NC acoustic signal is acoustically reproduced by the driver 1013 inside the headphone housing 1012, and noise (noise 1018 ′) is canceled near the ear of the listener 1011. .
- the noise 18 picked up by the microphone 1031 and the noise 1018 ′ in the headphone housing 1012 have different characteristics according to the difference in spatial position between them (the difference between outside and inside the headphone housing 1012). Therefore, in the FF system NC system, an NC acoustic signal is generated in consideration of the difference in spatial transfer function between the noise from the noise source 1018 picked up by the microphone 1031 and the noise 1018 'at the cancellation point Pc.
- an NC acoustic signal is generated using the FF filter circuit 1033.
- the FF filter circuit 1033 includes an FF filter operation unit 1332, an ADC 1331 provided in the preceding stage, and a DAC 1333 provided in the subsequent stage.
- the obtained analog acoustic signal collected by the microphone 1031 is supplied to the FF filter circuit 1033 through the microphone amplifier 1032, and AD-converted into a digital acoustic signal by the ADC 1331. Then, the digital acoustic signal is supplied to the FF filter calculation unit 1332.
- the FF filter operation unit 1332 is constituted by, for example, a DSP, and performs an operation as a digital filter (hereinafter also referred to as an FF filter operation) for generating a digital NC acoustic signal.
- the digital filter generates a digital NC sound signal having characteristics according to a filter coefficient as a parameter set in the digital sound signal input thereto.
- a predetermined filter coefficient is set in the digital filter as the FF filter operation unit 1332.
- a digital NC acoustic signal corresponding to the set filter coefficient is generated.
- the digital NC sound signal generated by the FF filter operation unit 1332 is DA-converted into an analog NC sound signal by the DAC 1333 and supplied to the adder circuit 1016 as an output signal of the FF filter circuit 1033.
- the addition circuit 1016 is supplied with an input sound signal (music signal or the like) S intended to be listened to by the listener 1011 through headphones via the sound signal input terminal 1014 and the equalizer 1015.
- the addition circuit 1016 adds the input acoustic signal and the NC acoustic signal as the output signal of the FF filter circuit 1033.
- the acoustic signal resulting from the addition by the addition circuit 1016 is supplied to the driver 1013 through the power amplifier 1017 and reproduced.
- the sound reproduced and emitted by the driver 1013 includes a sound reproduction component by the NC sound signal generated in the FF filter circuit 1033.
- the sound reproduction component of the NC sound signal and the noise 1018 ′ are acoustically synthesized, so that the noise 1018 ′ is reduced (cancelled) at the cancellation point Pc. )
- FIG. 17 is a diagram for explaining a transfer function of the FF system NC system of FIG.
- A is the transfer function of the power amplifier 1017
- D is the transfer function of the driver 1013
- M is the transfer function corresponding to the microphone 1031 and the microphone amplifier 1032.
- - ⁇ is the transfer function of the FF filter circuit 1033
- H is the transfer function of the space from the driver 1013 to the cancel point (auditory position) Pc
- E is the transfer function of the equalizer 1015
- F is the external noise
- Formula (4) will be represented by Formula (6).
- the noise N is canceled and the acoustic signal S to be listened to remains. Therefore, according to the FF system NC system of FIG. Sound can be heard.
- the filter coefficient of the FF filter calculation unit 1332 is, for example, the characteristics of the microphone 1031 and the microphone amplifier 1032 so that the listening sound P is expressed by the equation (6), that is, the equation (5) is established as much as possible. Is set based on the transfer function M as a driver, the transfer function D as a characteristic of the driver 1013, and the like.
- FIG. 18 is a block diagram showing a configuration example of an FF + FB-type NC system that performs FF + FB-type NC.
- the microphone 1021 installed inside the headphone housing 1012 collects, for example, noise (sound), sound output from the driver 1013, and the like. Sounded.
- An acoustic signal corresponding to the sound collected by the microphone 1021 is amplified by the microphone amplifier 1022 and supplied to the FB filter circuit 1023.
- the FB filter operation unit 1232 performs a filter operation (for example, a product-sum operation) using a predetermined filter coefficient for an acoustic signal corresponding to the sound collected by the microphone 1021.
- the obtained acoustic signal is supplied to the adding circuit 1016 as an FB-type NC acoustic signal.
- the microphone 1031 installed outside the headphone housing 1012 also collects, for example, noise (sound) or the like input thereto.
- An acoustic signal corresponding to the sound collected by the microphone 1031 is amplified by the microphone amplifier 1032 and supplied to the FF filter circuit 1033.
- the FF filter operation unit 1332 performs a filter operation (for example, product-sum operation) using a predetermined filter coefficient for the acoustic signal corresponding to the sound collected by the microphone 1031.
- the obtained acoustic signal is supplied to the adding circuit 1016 as an FF-type NC acoustic signal.
- the adder circuit 1016 In the adder circuit 1016, the FB-type NC acoustic signal from the FB filter circuit 1023, the FF-type NC acoustic signal from the FF filter circuit 1033, and the acoustic signal from the equalizer 1015 corresponding to the sound to be listened to. A certain input acoustic signal is added, and an acoustic signal obtained as a result of the addition is supplied to the power amplifier 1017.
- the power amplifier 1017 amplifies the acoustic signal from the addition circuit 1016 and supplies it to the driver 1013.
- the driver 1013 outputs (sounds) sound corresponding to the sound signal from the power amplifier 1017.
- the sound output from the driver 1013 includes sound corresponding to the FB-type NC sound signal and sound corresponding to the FF-type NC sound signal, but corresponds to the FB-type NC sound signal. And the sound corresponding to the FF type NC sound signal are added to noise at the cancellation point Pc until the sound output from the driver 1013 is transmitted through the real space and perceived by the listener 1011. To cancel with noise.
- the listening sound P that can be listened to by the listener 1011 is a sound in which noise is appropriately reduced.
- FIG. 19 is a block diagram illustrating a configuration example of a noise suppression system that performs noise suppression.
- the noise suppression system in FIG. 19 reduces (removes) noise by, for example, SS (Spectral Subtraction) method.
- an input acoustic signal that is an acoustic signal targeted for noise suppression is supplied to a non-speech interval detection unit 1401 and an FFT (FastFFourier Transform) processing unit 1042.
- FFT FastFastFFourier Transform
- the non-speech section detection unit 1401 detects a non-speech section (non-speech section) from the input acoustic signal, and supplies a non-speech section signal representing the non-speech section to the noise information storage unit 1407.
- the non-speech section detection unit 1401 detects, for example, a speech section from the input acoustic signal by a predetermined method, and detects sections other than the speech section as non-speech sections.
- the FFT processing unit 1402 performs FFT of the input acoustic signal, and supplies a spectrum, which is a frequency domain signal obtained as a result, to the spectrum average processing unit 1403 and the spectrum calculation processing unit 1404.
- the spectrum average processing unit 1403 averages the spectrum supplied from the FFT processing unit 1402 and supplies the average spectrum obtained as a result to the noise information storage unit 1407.
- the spectrum calculation processing unit 1404 subtracts the spectrum as noise information stored in the noise information storage unit 1407 from the spectrum from the FFT processing unit 402 and supplies the spectrum obtained as a result of the subtraction to the musical noise removal filter 1405. To do.
- the musical noise removal filter 1405 performs filtering for removing the musical noise on the spectrum from the spectrum calculation processing unit 1404, and supplies the spectrum after the removal of the musical noise to the IFFT (inverse FFT) processing unit 1406. .
- the IFFT processing unit 1406 performs IFFT of the spectrum from the musical noise removal filter 1405, and outputs an acoustic signal, which is a time domain signal obtained as a result, as an output acoustic signal after noise suppression.
- the noise information storage unit 1407 recognizes a non-speech segment based on the non-speech segment signal from the non-speech segment detector 1401 and averages the non-speech segment in the average spectrum supplied from the spectrum averaging processor 1403.
- the spectrum is stored as a noise spectrum.
- the input acoustic signal is supplied to the non-speech section detection unit 1401 and the FFT processing unit 1042.
- the non-speech section detection unit 1401 detects a non-speech section from the input sound signal, and supplies a non-speech section signal representing the non-speech section to the noise information storage unit 1407.
- the FFT processing unit 1402 performs FFT of the input acoustic signal, and a spectrum obtained as a result is supplied to the spectrum average processing unit 1403 and the spectrum calculation processing unit 1404.
- the spectrum average processing unit 1403 the spectrum from the FFT processing unit 1402 is averaged, and the average spectrum obtained as a result is supplied to the noise information storage unit 1407.
- the noise information storage unit 1407 recognizes a non-speech segment based on the non-speech segment signal from the non-speech segment detector 1401 and calculates the average spectrum of the non-speech segment out of the average spectrum from the spectrum averaging processor 1403. And memorize as noise spectrum.
- the spectrum calculation processing unit 1404 reads the latest spectrum of the noise spectrum as the noise information stored in the noise information storage unit 1407 and subtracts it from the spectrum from the FFT processing unit 402.
- the spectrum calculation processing unit 1404 supplies the spectrum obtained by the subtraction to the musical noise removal filter 1405 as a spectrum from which noise has been removed.
- the musical noise removal filter 1405 removes the spectral musical noise from the spectrum calculation processing unit 1404 and supplies it to the IFFT processing unit 1406.
- the IFFT processing unit 1406 performs IFFT of the spectrum from the musical noise removal filter 1405 and outputs an output acoustic signal obtained as a result.
- the output acoustic signal obtained as described above is a signal in which noise is reduced and the speech is enhanced.
- FIG. 20 is a perspective view showing an external configuration example of an application system to which the host device 10 and the input device 20 are applied.
- the host device 10 is applied (adopted) to a smartphone, and the input device 20 inserts a plug 23 into the jack 14 of the host device 10 that is a smartphone, whereby various data are stored in the host device 10. Applied to the input interface.
- FIG. 21 is a block diagram showing an example of the electrical configuration of the application system shown in FIG.
- FIG. 21 (the same applies to FIGS. 24 and 26 described later), in order to avoid complication of the drawing, some of the blocks in FIG. 2 are not shown.
- the host device 10 includes the clock generation unit 15, the resistor 33, the capacitor 43, the microphone detection unit 44, the correspondence detection unit 45, the interrupter 46, the register 48, and the I 2 C interface 49 of FIG. Although the blocks are not illustrated, the host device 10 of FIG. 21 includes these blocks as necessary.
- the input device 20 includes these blocks as necessary.
- the host device 10 that is a smartphone includes a signal processing block 11, an analog acoustic interface 12, a multiplexed data interface 13, a jack 14, and a clock generator 15 (not shown in FIG. 21), A DAC / Amp unit 201, a driver 202, a storage 203, an input / output unit 204, a communication mechanism 205, and an antenna 208 are included.
- the DAC / Amp unit 201 corresponds to, for example, the DAC 31 and the power amplifier 32 in FIG. 2 and DA-converts the digital acoustic signal supplied from the signal processing block 11 into an analog acoustic signal, and amplifies the jack. 14 and the driver 202.
- the driver 202 is an acoustic output unit (for example, a transducer configured by a coil and a diaphragm, which converts an acoustic signal into sound (sound wave) as air vibration) provided in the host device 10 that is a smartphone.
- the sound corresponding to the sound signal from the DAC / Amp unit 201 is output (sound emission).
- the storage 203 is a storage medium such as a hard disk or a semiconductor memory.
- the storage 203 stores (records) an acoustic signal or the like supplied from the signal processing block 11 according to the control of the signal processing block 11. Further, the acoustic signal or the like stored in the storage 203 is read according to the control of the signal processing block 11 and supplied to the signal processing block 11.
- the input / output unit 204 is, for example, a touch panel or a physical button, and is operated by the user.
- the input unit 204 supplies an operation signal corresponding to a user operation to the signal processing block 11.
- the input / output unit 204 displays a GUI (Graphical User Interface) such as a virtual button and other images according to the control from the signal processing block 11.
- GUI Graphic User Interface
- the communication mechanism 205 includes a transmission processing unit 206 and a reception processing unit 207, and functions as a communication interface that performs communication with a network such as the Internet or a base station of a mobile phone.
- the transmission processing unit 206 performs processing necessary for transmitting the acoustic (voice) signal supplied from the signal processing block 11 to the base station of the mobile phone, and supplies the processed signal to the antenna 208.
- the reception processing unit 207 is a process necessary to restore the other party's acoustic (voice) signal from the signal obtained by receiving the radio wave transmitted from the mobile phone base station supplied from the antenna 208. And the resulting acoustic signal is supplied to the signal processing block 11.
- device information related to the input device 20 is stored in the nonvolatile memory 85 of the input device 20, and the host device 10 reads out the device information stored in the nonvolatile memory 85 of the input device 20 to perform signal processing.
- signal processing suitable for the input device 20 can be performed based on the device information of the input device 20.
- NC Noise Cancel
- a method of configuring the NC system there is a method of implementing an NC processing function in the headphone itself, and, for example, a music player, a smartphone, and other headphones can be connected and an acoustic signal is reproduced.
- a method of implementing a function of performing NC processing in a signal reproduction device There is a method of implementing a function of performing NC processing in a signal reproduction device.
- a headphone equipped with the NC processing function can perform NC processing by itself, so it can be connected to any sound signal playback device (no connection), regardless of the NC processing. It can be performed.
- the FB filter computation and FF filter computation appropriate for headphones connected to the acoustic signal reproduction device (hereinafter also referred to as connected headphones)
- the filter coefficients corresponding to the connected headphones are stored in the acoustic signal reproduction device, and the NC processing appropriate for the connected headphones can be performed. it can.
- a coefficient set of filter coefficients for example, a plurality of coefficient sets such as a coefficient set NCHP-1 corresponding to the first headphones and a coefficient set NCHP-2 corresponding to the second headphones are reproduced as an acoustic signal.
- the user selects the coefficient set NCHP-1 corresponding to the first headphone, and the sound signal reproducing device
- the user selects the coefficient set NCHP-2 corresponding to the second headphone, so that the acoustic signal reproduction device has the first and second headphones. Whichever of these is connected, NC processing appropriate for the headphones connected to the acoustic signal reproducing device can be performed.
- a headphone vendor releases a new third headphone and a coefficient set NCHP corresponding to the third headphone.
- -3 is released on a network such as the Internet, and if the acoustic signal playback device has a network connection function for connecting to the network, the acoustic signal playback device downloads the coefficient set NCHP-3 on the network. By doing so, it is possible to perform NC processing appropriate for the third headphone.
- the acoustic signal reproduction device does not have a network connection function, when the new third headphones are put on the market, the acoustic signal reproduction device will use the coefficient set NCHP- corresponding to the new third headphones. 3 cannot be obtained by downloading.
- the host device 10 and the input device 20 are applied to an NC system, and the host device 10 and the input device 20 are configured as an acoustic signal reproduction device and a headphone (headset), respectively. Even if the host device 10 as the acoustic signal reproducing apparatus does not have a network connection function, when the input device 20 is released as the third headphone, the host device 10 as the acoustic signal reproducing apparatus is The coefficient set NCHP-3 corresponding to the input device 20 as the third headphone can be acquired.
- a coefficient set (hereinafter also referred to as a corresponding coefficient set) corresponding to the input device 20 as the headphone is stored in the device information stored in the nonvolatile memory 85 of the input device 20 as the headphone, and the sound is stored.
- the device information stored in the nonvolatile memory 85 of the input device 20 in the host device 10 as the signal reproducing device it is possible to acquire the corresponding coefficient set included in the device information.
- the coefficient set (corresponding coefficient set) corresponding to the input device 20 as the headphone is acquired, and the headphones It is possible to perform appropriate NC processing.
- the device information stored in the nonvolatile memory 85 of the input device 20 as a headphone can include identification information for identifying the input device 20 as the headphone instead of the corresponding coefficient set.
- the device information can include both the corresponding coefficient set and the identification information.
- the identification information for example, a combination of a vendor ID similar to that assigned to a USB (Universal Serial Bus) device manufacturer and a product ID representing a product model or model, or a UUID (Universally Unique Identifier) ) Etc. can be adopted.
- a vendor ID similar to that assigned to a USB (Universal Serial Bus) device manufacturer and a product ID representing a product model or model, or a UUID (Universally Unique Identifier) ) Etc.
- UUID Universal Unique Identifier
- the host device 10 as an acoustic signal reproduction device includes identification information in the signal processing block 11 and a coefficient set for performing NC processing appropriate for the input device 20 such as headphones identified by the identification information. It is assumed that a coefficient database which is a database associated with is incorporated.
- the device information stored in the nonvolatile memory 85 of the input device 20 as a headphone includes at least identification information of the corresponding coefficient set and the identification information.
- the host device 10 when the input device 20 as a headphone is connected to the host device 10 as an acoustic signal reproducing device, the host device 10 reads device information from the input device 20 and is included in the device information. It is determined whether or not the identification information that matches the identification information is stored in the coefficient database.
- the host device 10 When the identification information that matches the identification information of the input device 20 is stored in the coefficient database of the host device 10, the host device 10 as the acoustic signal reproduction device matches the identification information of the input device 20 in the coefficient database.
- the coefficient set associated with the identification information is reflected in the digital filter that performs the NC filter calculation, and the NC process is performed.
- the headphone side storage information is read from the headphones, and the signal processing characteristics of the signal processing device are set based on the headphone side storage information.
- the host device 10 as the acoustic signal reproducing device includes the device information read from the input device 20 as the headphone in the device information. Check if the coefficient set (corresponding coefficient set) is included.
- the host device 10 confirms whether the coefficient set included in the device information matches the NC function platform installed in the host device 10. To do.
- the NC function platform refers to, for example, the type of DSP that is the hardware that performs NC filter computation, the NC filter computation program (configuration of the digital filter that performs NC filter computation) performed by the DSP, and the like. means.
- the host device 10 determines that the coefficient set included in the device information is It is reflected in the digital filter that performs NC filter calculation, and NC processing is performed.
- the coefficient set does not match the NC function platform installed in the host device 10. In this case, the host device 10 turns off the NC function.
- the host device 10 as the acoustic signal reproduction device can input the input device 20. Since the device information stored in the non-volatile memory 85 can be read out and NC processing can be performed using the corresponding coefficient set included in the device information, the host device 10 does not have a network connection function. However, it is possible to acquire a corresponding coefficient set of the input device 20 as a headphone, and perform NC processing appropriate for the input device 20 as a headphone using the corresponding coefficient set.
- the identification information of the input device 20 matches in the coefficient database.
- a coefficient set associated with the identification information is used, and the coefficient set included in the device information is used only when the identification information that matches the identification information of the input device 20 is not stored in the coefficient database.
- the coefficient set stored in the coefficient database is used in preference to the coefficient set included in the device information. This is due to the following reason.
- a corresponding coefficient set hereinafter also referred to as an initial coefficient set
- Corresponding coefficient sets hereinafter, also referred to as update coefficient sets
- the host device 10 When the update coefficient set is made public on the network, when the host device 10 as the acoustic signal reproducing device has a network connection function, the host device 10 downloads the update coefficient set, and the coefficient database. Can be updated.
- the coefficient set stored in the coefficient database is used in preference to the coefficient set included in the device information, whereby the initial coefficient set included in the device information is used. Therefore, more appropriate NC processing using the update coefficient set can be performed.
- the host device 10 When the host device 10 as the acoustic signal reproducing apparatus does not have a network connection function, but the initial coefficient set is stored in the coefficient database, the host device 10 stores the coefficient coefficient database. NC processing is performed using the initial coefficient set. Further, when the host device 10 as the acoustic signal reproducing apparatus does not have a network connection function and the initial coefficient set is not stored in the coefficient database, the host device 10 reads the device read from the input device 20. NC processing is performed using the initial coefficient set included in the information.
- the host device 10 as an acoustic signal reproduction device has a function of performing NC processing has been described above.
- the host device 10 performs, for example, an equalizer that performs sound quality correction, Virtualphones Technology ( Registered information), noise suppression, beam forming, and other acoustic signal processing functions for processing acoustic signals, the processing information for performing acoustic signal processing appropriate for the input device 20 as a headphone Can be included in the device information.
- the host device 10 as the acoustic signal reproduction device device information is read from the input device 20 as the headphone, and by setting the characteristics of the acoustic signal processing based on the processing information included in the device information, Sound signal processing appropriate for the input device 20 as a headphone can be performed.
- the device information includes the filter coefficient (coefficient set) of the digital filter that performs the NC filter calculation.
- the device information includes parameters for the NC filter calculation and , Characteristic information representing the characteristics of the acoustic transducer of the input device 20 as a headphone, that is, the microphone 81 i and the drivers 61L and 61R can be included.
- the parameters for the NC filter calculation include, for example, the type of digital filter that performs the NC filter calculation, the center frequency, the gain, and the like.
- the characteristic information of the transducer includes, for example, the sensitivity of the microphone 81 i and the drivers 61L and 61R, frequency characteristics (amplitude characteristics and phase shift characteristics), and the like.
- the host device 10 as the acoustic signal reproducing device can select an appropriate NC from the NC filter calculation parameters or transducer characteristic information.
- the filter coefficient of the digital filter that performs the NC filter operation for executing the above process is obtained.
- the device information includes, for example, a DSP register setting value (register setting value) as hardware for realizing a digital filter that performs NC filter calculation.
- a DSP register setting value register setting value
- the NC processing can be performed by setting the DSP register as hardware for realizing the digital filter that performs the NC filter operation.
- the method of including parameters and the like in the device information can also be applied when performing acoustic signal processing other than NC processing, such as an equalizer.
- the device information of the input device 20 includes the characteristic information of the transducer and the NC information obtained from the characteristic information.
- the device information including the filter coefficient for processing in the input device 20 it is required to reduce the size, power consumption, and cost of the input device 20.
- the characteristic information of the transducer due to a measurement error by an operator who measures the characteristic information, replacement of the transducer (microphone 81 i and drivers 61L and 61R) accompanying repair of the input device 20 as a headphone, etc., In some cases, re-measurement of the characteristic information of the transducer is performed.
- the device information it is necessary to update the device information to the device information including the characteristic information after the remeasurement and the filter coefficient obtained from the characteristic information after the remeasurement.
- the input device 20 when the device information is stored in the input device 20, it is required that the input device 20 be easily updated in addition to downsizing, power saving and cost reduction.
- the nonvolatile memory 85 for storing device information is small and power saving.
- There are inexpensive methods such as using OTP (memory) or EPROM.
- OTP can only be written once (data in the storage area where data has been written cannot be rewritten).
- EPROM can be rewritten by erasing data written in the storage area by irradiating ultraviolet rays, but EPROM is mounted on the input device 20 in the EPROM. Since it is not practical to irradiate ultraviolet rays, it can be said that EPROM is a memory that can be written only once, as in the case of OTP.
- the device information stored in the non-volatile memory 85 adopting OTP, EPROM or the like that can be written only once as described above, in order to easily update the device information, the following is performed. Introduce device information update mechanism.
- FIG. 22 is a diagram illustrating an example of device information stored in the nonvolatile memory 85.
- nonvolatile memory 85 device information is stored (written) in a chunk structure.
- a chunk is a group (structure) of data related to one category such as a certain function.
- Basic information of the input device 20 is registered in the total header chunk, and information on a predetermined function is registered in the function data chunk.
- an area of a predetermined size such as 2 bytes is provided as a chunk header for registering the function type (function TYPE) and the chunk size.
- the function type indicates what function (category) data is registered in the chunk in which the function type is registered.
- the chunk size represents, for example, the size (number of bytes) of the chunk including the chunk header.
- the host device 10 updates chunk data of a certain function type stored in the nonvolatile memory 85 of the input device 20, the host device 10 appends the chunk in which the updated data is registered to the free area of the nonvolatile memory 85. To do.
- the host device 10 When there are a plurality of chunks of the same function type in the device information read from the nonvolatile memory 85 of the input device 20, the host device 10 is the newest of the plurality of chunks of the same function type.
- the chunk (the last written chunk) is regarded as a valid chunk, and signal processing such as NC or equalizer processing is performed using data registered in the valid chunk.
- the newest chunk of the plurality of chunks of the same function type is selected.
- the user can select which chunk data to use for the equalizer processing.
- which one of a plurality of chunks of the same function type is the newest chunk is determined based on the writing date and time by registering the writing date and time of the chunk when writing the chunk, for example. Can be recognized.
- the chunks in a predetermined order such as ascending order of the addresses of the non-volatile memory 85, it is determined which of the plurality of chunks of the same function type is the newest chunk. It can be recognized based on the address where the chunk is written.
- FIG. 22 shows an example of device information stored in the nonvolatile memory 85 in the chunk structure as described above.
- chunks are written in ascending order of addresses of the nonvolatile memory 85, for example.
- a 2-byte chunk header is arranged at the beginning of the chunk, and the function type and chunk size are registered in the chunk header.
- the 2-byte chunk header has a 4-bit function type, 4-bit function type sub-information (function TYPE-Sub information), and a 1-byte chunk size from the beginning.
- the function type indicates what function data is registered in the chunk as described above.
- the 4-bit “0000” as the function type is reserved (Rsv (Reserved)), and the 4-bit “0001” as the function type indicates that the chunk is a total header chunk (Total Header). .
- the chunk indicates that the data relating to the microphone 81 i such characteristic information of the microphone 81 i having an input device 20 (Mic) are registered, as the function type
- the 4-bit “0011” indicates that data (Drv) related to the drivers 61L and 61R such as the characteristic information of the drivers 61L and 61R included in the input device 20 is registered in the chunk.
- the 4-bit “0100” as the function type indicates that data (EQ_M) related to the equalizer for music is registered in the chunk, and the 4-bit “0101” as the function type is flat in the chunk. Indicates that the data (EQ_F) related to the equalizer that gives the frequency characteristics is registered.
- the function type sub-information is auxiliary information of the function type, which is arbitrary information.
- the chunk size represents the size of the chunk including the chunk header in bytes.
- the chunk size is 1-byte data, and the maximum number of bytes that can be represented by the 1-byte chunk size is 255 bytes, so the maximum size of one chunk is 255 bytes.
- the chunk in which the function type is 4 bits “0010” and the data (Mic) related to the microphone 81 i such as the characteristic information of the microphone 81 i included in the input device 20 is registered is referred to as a Mic chunk hereinafter.
- EQ_M chunk a chunk whose function type is 4 bits “0100” and data related to music equalizer (EQ_M) is registered is also called an EQ_M chunk.
- NC chunks in which NC-related data is registered are also called NC chunks.
- the total header chunk includes, for example, a function (such as a headphone or a headset) that the input device 20 has, a vendor ID, a product ID, and an operation unit (switch 80 that can be operated by the user that the input device 20 has). Etc.), the basic information of the input device 20 is registered.
- the Mic chunks for example, the number of microphones 81 i having an input device 20 (Mic Number) and the characteristic information of the microphone 81 i (characteristic data) and the like are registered.
- the EQ_M chunk includes, for example, information related to a DSP (corresponding DSP) that can perform the equalizer process when the host device 10 to which the input device 20 is connected performs the equalizer process, and an equalizer process algorithm. Algorithm information, equalizer coefficients used for equalizer processing, and the like are registered.
- the NC chunk includes, for example, information on a DSP (corresponding DSP) that can perform NC processing when the host device 10 to which the input device 20 is connected performs NC processing, and an NC processing algorithm. Algorithm information, filter coefficients used for NC processing (Noise Canceling Filter coefficients), and the like are registered.
- a DSP corresponding DSP
- Algorithm information, filter coefficients used for NC processing (Noise Canceling Filter coefficients), and the like are registered.
- the chunk in which the updated data is registered is nonvolatile.
- the free space in the memory 85 for example, the free space is added to a free space with a smaller address.
- the host device 10 reads a chunk as device information stored in the nonvolatile memory 85 of the input device 20.
- the host device 10 Signal processing is performed using the newest chunk (the chunk with the highest address) as a valid chunk.
- the total header chunk and the functional data chunk can adopt different structures instead of the same structure.
- the chunk read / write control in the host device 10 that reads / writes the chunk from / to the nonvolatile memory 85 of the input device 20 is simplified. be able to.
- the total header chunk can be written at the head of the address of the nonvolatile memory 85 as shown in FIG.
- the total header chunk can be written at any position other than the topmost address of the nonvolatile memory 85.
- the maximum chunk size is set to 255 bytes. However, by making it possible to register information (flag) indicating that a subsequent chunk exists in the chunk, the maximum chunk size can be registered.
- the size can be substantially larger than 255 bytes.
- FIG. 23 is a perspective view showing an external configuration example of a first system to which the application system of FIGS. 20 and 21 is applied.
- the host device 10 is applied to a smartphone equipped with a music playback application, and the input device 20 is applied to a headset.
- FIG. 24 is a block diagram showing an example of the electrical configuration of the first system of FIG.
- the signal processing block 11 includes a sequence control unit 211, a filter / coefficient control unit 212, an FB filter calculation unit 213, an FF filter calculation unit 214, a signal processing unit 215, an equalizer (EQ) 216, and an addition circuit 217. Is configured to function as
- the multiplexed data interface 13 receives device information read from the nonvolatile memory 85 of the input device 20 (transmitted from the input device 20 to the host device 10. Device information included in the multiplexed data) is supplied.
- the FB filter calculation unit 213 and the FF filter calculation unit 214 collect the sound collected by the microphone 81 i of the input device 20 included in the multiplexed data transmitted from the input device 20 to the host device 10. Are supplied from the multiplexed data interface 13.
- the sound signal of the music stored in the storage 203 is supplied to the signal processing unit 215.
- the sequence control unit 211 controls the signal processing block 11 and other blocks based on the device information supplied from the multiplexed data interface 13.
- the filter / coefficient control unit 212 sets the filter coefficient of the FB filter calculation performed by the FB filter calculation unit 213 in the FB filter calculation unit 213 based on the device information supplied from the multiplexed data interface 13. Further, the filter / coefficient control unit 212 sets the filter coefficient of the FF filter calculation performed by the FF filter calculation unit 214 in the FF filter calculation unit 214 based on the device information supplied from the multiplexed data interface 13.
- the FB filter calculation unit 213 performs the FB filter calculation on the acoustic signal supplied from the multiplexed data interface 13 using the filter coefficient set by the filter / coefficient control unit 212, thereby obtaining the FB filter of FIG.
- An FB-type NC acoustic signal similar to that obtained by the filter calculation unit 1232 is generated and supplied to the adder circuit 217.
- the FF filter operation unit 214 performs the FF filter operation on the acoustic signal supplied from the multiplexed data interface 13 using the filter coefficient set by the filter / coefficient control unit 212, thereby obtaining the FF filter of FIG.
- the FF NC sound signal similar to that obtained by the filter calculation unit 1332 is generated and supplied to the adder circuit 217.
- the signal processing unit 215 performs predetermined signal processing on the acoustic signal of the music supplied from the storage 203 and supplies the processed signal to the equalizer 216.
- the equalizer 216 corrects the sound quality of the sound signal of the music from the signal processing unit 215 and supplies it to the adder circuit 217.
- the adder circuit 217 adds the FB-type NC acoustic signal from the FB filter computation unit 213, the FF-type NC acoustic signal from the FF filter computation unit 214, and the music sound signal from the equalizer 216. Then, a noise-reduced acoustic signal that is a sound (sound wave) from which noise has been removed by noise acting (adding) in real space is obtained and supplied to the DAC / Amp unit 201.
- the noise-reduced acoustic signal supplied to the DAC / Amp unit 201 is supplied to the drivers 61L and 61R via the jack 14 and the plug 23, for example, so that the corresponding sound is received from the drivers 61L and 61R. Is output.
- the host device 10 as a smartphone and the input device 20 as a headset are configured by inserting the plug 23 of the input device 20 into the jack 14 of the host device. It functions as an NC system that performs NC processing.
- characteristic information such as sensitivity and frequency characteristics (amplitude characteristics and phase shift characteristics) of the microphone 81 i and the drivers 61L and 61R are included in the device information in advance in a mass production process. And stored in the nonvolatile memory 85.
- the device information stored in the nonvolatile memory 85 of the input device 20 can be read by the host device 10 connected to the input device 20 as described above.
- Input device 20 has five microphones 81 0 to 81 4, the one microphone 81 0 may be used as an audio microphone (Speech-Mic).
- the microphone 81 1 corresponds to the microphone 1031 that is installed outside the headphone housing 1012 in the FF NC system of FIG. 16 and collects external noise, and is used for FF NC processing. , Used as a microphone (FF-NC-Mic (R)) for collecting R channel noise.
- Microphone 81 2 is the microphone pair microphone 81 1, used for processing the NC of FF scheme, is used as a microphone for collecting noise L channel (FF-NC-Mic (L )).
- Microphone 81 3 is the NC system of the FB scheme shown in FIG 14, installed inside the headphone housing 1012, corresponds to the microphone 1021 for collecting the internal noise, used in the processing of the NC in the FB scheme, R Used as a microphone (FB-NC-Mic (R)) to collect channel noise.
- Microphone 81 4 the microphone pair with microphone 81 3, used for processing the NC of the FB scheme, is used as a microphone for collecting noise L channel (FB-NC-Mic (L )).
- the multiplexed data interface 13 reads device information from the nonvolatile memory 85 of the input device 20 and supplies the device information to the sequence control unit 211 and the filter / coefficient control unit 212.
- the filter / coefficient control unit 212 based on the filter coefficient included in the device information, the filter coefficient of the FB filter calculation performed by the FB filter calculation unit 213, and the filter coefficient of the FF filter calculation performed by the FF filter calculation unit 214 Set up.
- the sequence control unit 211 controls the gain (sensitivity) of the amplifier 82 i and the gain of the DAC / Amp unit 201 based on the transducer characteristic information included in the device information. This is done so that
- the filter / coefficient control unit 212 associates the identification information of the input device 20 with a coefficient set for performing NC processing appropriate for the input device 20 such as a headset identified by the identification information.
- a built-in coefficient database can be stored.
- the filter / coefficient control unit 212 reads a coefficient set associated with the same identification information as the identification information included in the device information in the coefficient database based on the identification information included in the device information. It can be set as a filter coefficient of the filter calculation unit 213 and the FF filter calculation unit 214.
- the filter coefficient for the FB filter calculation and the filter coefficient for the FF filter calculation are set based on the filter coefficient included in the device information of the input device 20 as the headset, the input device 20 In the mass production process, measurement of characteristic information and writing of characteristic information and a coefficient set (filter coefficient) obtained from the characteristic information to the nonvolatile memory 85 are necessary. This adjustment is unnecessary, and a great cost for the adjustment can be reduced.
- NC processing filter coefficients (FB filter calculation filter coefficients and FF filter calculation filter coefficients) are set based on the filter coefficients included in the device information of the input device 20 as a headset.
- the above-described transducer can be obtained by simply writing device information including filter coefficients and the like for performing NC processing appropriate for the input device 20 in the nonvolatile memory 85 of the input device 20. Adjustment of etc. becomes unnecessary.
- the user himself / herself enjoys the effect of the NC processing appropriate for the input device 20 as the headset without performing an operation for selecting the filter coefficient of the NC processing through UI (User Interface) or the like. be able to.
- UI User Interface
- the processing of the NC processing is performed.
- the NC based on the filter coefficient included in the device information of the input device 20 as the headset Such a situation can be avoided when the filter coefficient of the process is set.
- the setting of the frequency characteristics of the equalizer 216 as appropriate music characteristics when listening to music using the input device 20 as a headset is stored in the device information of the input device 20.
- the process of the equalizer 216 according to the music characteristics it is possible to perform an appropriate sound quality correction in the equalizer 216 when listening to music using the input device 20 as a headset.
- the device information includes sound field processing such as high sound quality processing (band expansion, bit expansion) appropriate for the input device 20 as a headset, dynamics processing (compressor, limiter), surround processing, etc. Processing information on the sense of spread and out-of-head localization) can be included.
- sound field processing such as high sound quality processing (band expansion, bit expansion) appropriate for the input device 20 as a headset, dynamics processing (compressor, limiter), surround processing, etc. Processing information on the sense of spread and out-of-head localization) can be included.
- the device information can include information necessary for surround processing obtained from (for example, filter coefficients of FIR (Finite Impulse Response) filter and IIR (Infinite Impulse Response) filter) as processing information.
- FIR Finite Impulse Response
- IIR Intelligent Impulse Response
- the filter / coefficient control unit 212 is associated with identification information of the input device 20 and processing information for performing processing appropriate for the input device 20 such as a headset identified by the identification information. Processing information associated with the same identification information as the identification information included in the device information can be read from the database by incorporating the database.
- a database can be built on a network such as the Internet in addition to being built in the filter / coefficient control unit 212 or the like.
- FIG. 25 is a perspective view showing an external configuration example of a second system to which the application system of FIGS. 20 and 21 is applied.
- the host device 10 is applied to a smartphone on which a call application is mounted, and the input device 20 is applied to a headset having a microphone array.
- FIG. 26 is a block diagram showing an example of the electrical configuration of the second system of FIG.
- the signal processing block 11 is configured to function as a sequence control unit 211, a filter / coefficient control unit 212, and a beamforming / noise suppression unit 231.
- Beamforming / noise suppression section 231 includes an input device 20 to the multiplexed data sent to the host device 10, corresponding to the sound is collected by the microphone 81 0 to 81 4 of the input device 20 Acoustic signals # 0 to # 4 are supplied from the multiplexed data interface 13.
- Beamforming / noise suppression unit 231 using acoustic signals # 0 to # 4 to the microphone 81 0 of the input device 20 as a headset corresponding to sound is collected by the 81 4, as described in FIG. 19 By performing noise suppression and beam forming, the voice signal of the user wearing the input device 20 as a headset is emphasized.
- the audio signal obtained by the beamforming / noise suppression unit 231 is supplied to the transmission processing unit 206 and transmitted as telephone audio via the antenna 208.
- the input device 20 as a headset having five microphones 81 0 to the microphone array consists of 81 4, a host device as a smartphone 10, based on the device information, the host device 10 and the input device 20 collect a sound with a high S / N in an environment with a low S / N (Signal to Noise ratio). Functions as a / N system.
- the input device 20 in the device information stored in the nonvolatile memory 85 of the input device 20 as a headset, the input device 20 is a headset compatible with beam forming,
- the input device 20 includes all types of processing algorithm such as beam forming, and information on parameters necessary for processing such as beam forming.
- the device information, included and characteristic information of the microphone 81 i necessary for calibration such as a microphone 81 i (Calibration) or the like, obtained from the characteristic information, the information of the filter coefficient or the like used for the audio signal processing It is.
- a database (hereinafter also referred to as a device information database) associated with the identification information of the input device 20 is configured, and the device information database is built in the signal processing block 11, or Can be published on the network. Then, the host device 10 can acquire information such as parameters for performing appropriate processing for the input device 20 from the device information database using the identification information included in the device information read from the input device 20 as a keyword. .
- a microphone acoustic signal for one channel can be transmitted to the host device 20, but in the second system configured by the host device 10 and the input device 20, From the input device 20, the sound signals of the microphones of a plurality of channels such as 5 channels are transmitted to the host device 10 that can expect abundant calculation resources. Based on the device information in the signal processing block 11 of the host device 10.
- the acoustic signal from the input device 20 can be subjected to beam forming appropriate for the input device 20, noise suppression processing, and the like.
- FIG. 27 is a perspective view showing an external configuration example of a third system to which the application system of FIGS. 20 and 21 is applied.
- the electrical configuration of the third system in FIG. 27 is the same as the electrical configuration example shown in FIG. 21, for example.
- the host device 10 is applied to a smartphone equipped with an application for monitoring surrounding sounds in real time
- the input device 20 is a monitor microphone that includes a plurality of four microphones 81 1 to 8 14 and the like. It is applied to over-ear headphones with a microphone.
- the device information stored in the nonvolatile memory 85 includes that the input device 20 is an over-ear headphone having a function of monitoring surrounding sounds in real time, or a microphone 81. All information necessary for each calibration such as i is included.
- the signal processing block 11 is suitable for the input device 20 based on the device information of the input device 20 and necessary user operations.
- a functional block for processing is constructed.
- the signal processing block 11 of the host device 10 uses the input device 20 based on the device information.
- the acoustic signals of the four microphones 81 1 to 8 14 from the above can be subjected to beam forming appropriate for the input device 20, noise suppression processing, and the like. it can.
- the beam forming and noise suppression processing of the signal processing block 11 it is possible to generate, for example, a directivity-oriented acoustic signal, an acoustic signal in which all surrounding audio signals are emphasized, and the like.
- the sound signal processed by the signal processing block 11 (FIG. 21) of the host device 10 is transmitted via the DAC / Amp unit 201.
- the sound is transmitted to the input device 20 and the corresponding sound is output from the drivers 61L and 61R.
- the signal processing block 11 of the host device 10 performs echo cancellation and noise suppression in addition to beam forming and noise suppression. Processing such as howling suppression can be performed.
- the signal processing block 11 can also perform the above-described FF + FB NC processing.
- FIG. 28 is a perspective view showing an external configuration example of a fourth system to which the application system of FIGS. 20 and 21 is applied.
- the electrical configuration of the fourth system in FIG. 28 is the same as the electrical configuration example shown in FIG. 21, for example.
- the host device 10 a voice (telephone) has been applied to a smartphone implementing the application for meeting, input device 20, to five microphones 81 0 has a plurality of microphones 81 4 such as, as it were deferred It is applied to a type (conference) microphone system.
- the host device 10 as a smartphone has a camera
- an input device 20 as a stationary microphone system is connected to the host device 10
- an application for performing a voice conference is started on the host device 10 based on the device information.
- high-accuracy acoustics such as beam forming appropriate for the input device 20, noise suppression, echo canceller, howling suppression, etc. are obtained for the acoustic signal from the input device 20 based on the device information.
- Signal processing or the like is performed, and thereby, directivity tracking in the dominant direction of voice, echo cancellation, and the like are executed.
- the acoustic signal obtained by processing the acoustic signal from the input device 20 is transmitted from the communication mechanism 205 (FIG. 21) to the other party of the audio conference via the antenna 208.
- an acoustic signal transmitted from the other party of the audio conference is received by the communication mechanism 205 via the antenna 208, and in the signal processing block 11, for the input device 20 based on the device information. After appropriate NC processing or the like, the input device 20 is supplied. In the input device 20, sound corresponding to the sound signal from the signal processing block 11 is output from the drivers 61L and 61R.
- FIG. 29 is a perspective view showing an external configuration example of a fifth system to which the application system of FIGS. 20 and 21 is applied.
- the electrical configuration of the fifth system in FIG. 29 is the same as the electrical configuration example shown in FIG. 21, for example.
- the host device 10 is applied to a smartphone equipped with a recording application that records an acoustic signal in an existing multi-channel audio format such as 5.1ch
- the input device 20 includes four microphones 81 1 to 81. 4 and 5 mic 81 0 to a plurality of built-in microphone 81 4 or the like and is applied to the accessory microphone system as one of the accessories such as a video camera.
- the host device 10 executes a recording application based on the device information and records an acoustic signal in a multi-channel audio format. To function as a system.
- the signal processing block 11 of the host device 10 needs to perform beam forming appropriate for the input device 20 and reduce wind noise for the acoustic signal from the input device 20 based on the device information. Processing is performed, and the resulting acoustic signal is recorded in the storage 203 (FIG. 21), for example, in a multi-channel audio format.
- the fifth system records multi-channel audio recording by recording an image captured by the camera in the host device 10 in the storage 203 as well.
- FIG. 30 is a perspective view showing an external configuration example of a sixth system to which the application system of FIGS. 20 and 21 is applied.
- the electrical configuration of the sixth system in FIG. 30 is the same as the electrical configuration example shown in FIG. 21, for example.
- the host device 10 is applied to a smartphone equipped with a mixer application for mixing acoustic signals
- the input device 20 is applied to an input device that receives input of acoustic signals at the line level.
- the input device 20 are the input device that receives an input of the acoustic signal at the line level, instead of the microphone 81 i in FIG. 21, or is provided with a microphone 81 i, a line level Are provided with a plurality of line input terminals (jacks) for inputting a sound signal of the above and an instrument input terminal corresponding to an electric guitar or the like.
- the input device 20 as an input device, plugs of a plurality of musical instruments (including microphones) are inserted into line input terminals or musical instrument input terminals, and the acoustic signals of the musical instruments output from the plurality of musical instruments through the plugs. Can be entered.
- the input device 20 as an input device can transmit the input acoustic signal of the musical instrument to the host device 20 in the same manner as the acoustic signal obtained by the microphone 81 i .
- a mixer application is started in the host device 10 based on the device information.
- signal processing such as processing for adjusting the mixing balance of the acoustic signals of the musical instruments from the input device 20 and processing for applying effects to the acoustic signals of the individual musical instruments is performed.
- the acoustic signal of the instrument from the input device 20 (including the acoustic signal after being subjected to signal processing in the signal processing block 11) can be recorded in the storage 203 (FIG. 21). .
- FIG. 31 is a perspective view showing an external configuration example of a seventh system to which the application system of FIGS. 20 and 21 is applied.
- the electrical configuration of the seventh system in FIG. 31 is the same as the electrical configuration example shown in FIG. 21, for example.
- the host device 10 is applied to a smartphone equipped with a recording application that records a sensor signal output from the sensor, and the input device 20 inputs a sensor signal of a biological sensor that senses biological information. It is applied to the sensor input device which receives.
- the input device 20 is a sensor input device as described above, a plurality of input terminals (in addition to the microphone 81 i in FIG. 21 or together with the microphone 81 i) for inputting sensor signals ( Jack) is provided.
- the input device 20 as a sensor input device includes a plurality of biological sensors by inserting plugs of a plurality of biological sensors (for example, a sensor for sensing eye movements, a sensor for sensing brain waves, etc.) into an input terminal.
- the sensor signal output through the plug can be input.
- the input device 20 as the sensor input device can transmit the input sensor signal to the host device 20 in the same manner as the acoustic signal obtained by the microphone 81 i .
- the host application 10 when an input device 20 as a sensor input device is connected to the host device 10, the host application 10 starts a recording application based on the device information.
- processing necessary for the sensor signal of the biosensor from the input device 20 is performed and recorded in the storage 203.
- the sensor signals of a plurality of biological sensors are sent to the host via the 4-pole plug 23 of the input device 20 and the 4-pole jack 14 of the host device 10.
- the data can be input to the device 10 and recorded.
- the host device 10 transmits the sensor signal of the biometric sensor from the input device 20 to the cloud (the computer that configures it) as necessary, or sends the sensor signal in the cloud.
- a feedback result obtained by processing can be received, displayed, recorded in the storage 203, or the like.
- FIG. 32 is a block diagram illustrating an eighth detailed configuration example of the host device 10 and the input device 20.
- one of the two terminals 71A and 71B is selected for easy understanding.
- the input device 20 is configured by using the switch 71 that can be switched.
- an analog switch is also used as the switch 71, for example.
- FIG. 32 is directed to the sixth detailed configuration example of FIG. 8, and the host device 10 and the input device 20 when the switches 41 and 71 of the sixth detailed configuration example are mounted using analog switches.
- the example of a structure is shown.
- FIG. 32 portions corresponding to those in FIG. 8 are denoted by the same reference numerals, and description thereof will be omitted below as appropriate.
- the switches 41 and 71 can be mounted using an analog switch.
- the host device 10 includes a signal processing block 11, a clock generation unit 15, a DAC 31, a power amplifier 32, a resistor 33, an interrupter 46, a transmission / reception processing unit 47, a register 48, an I 2 C interface 49, a plug detection unit 101, 8 is common to the case of FIG. 8 in that the authentication pattern output unit 102 and the pattern detection unit 103 are provided.
- the host device 10 is different from the case of FIG. 8 in that a switch unit 401 is provided instead of the switch 41 and a coil 402 and a capacitor 403 are newly provided. To do.
- the analog acoustic interface 12 is configured in the same manner as in FIG.
- the multiplexed data interface 13 includes an interrupter 46, a transmission / reception processing unit 47, a register 48, an I 2 C interface 49, a plug detection unit 101, an authentication pattern output unit 102, a pattern detection unit 103, A switch unit 401, a coil 402, and a capacitor 403 are included.
- the input device 20 includes drivers 61L and 61R, an LDO 74, a control unit 75, a PLL 77, a transmission processing unit 78, a switch 80, microphones 81 0 to 81 4 , amplifiers 82 0 to 82 4 , resistors 83 0 to 83 4 , ADCs 84 0 to 84 4 , nonvolatile memory 85, power detection unit 111, and authentication pattern output unit 112 are common to the case of FIG.
- the input device 20 is provided with a switch unit 411 instead of the switch 71, and a capacitor 412, a coil 413, and a capacitor 414 are newly provided. It is different from the case.
- the analog acoustic interface 21 is configured in the same manner as in FIG.
- the multiplexed data interface 22 includes an LDO 74, a control unit 75, a PLL 77, a transmission processing unit 78, a switch 80, microphones 81 0 to 81 4 , amplifiers 82 0 to 82 4 , and resistors 83 0. to 83 4, ADC 84 0 to 84 4, the nonvolatile memory 85, a power detection unit 111, the authentication pattern output unit 111, a switch unit 411, a capacitor 412, a coil 413 and consists of a capacitor 414.
- the switch unit 401 is configured using an analog switch and has terminals J1, J2, J3, and J4.
- Terminals J1 the power is a power supply terminal to (predetermined voltage) is applied, in FIG. 32, is connected to the power supply V D.
- the terminals J2 and J3 are terminals to be turned on and off, and in the switch unit 401, between the terminals J2 and J3 is turned on (conductive state) or turned off (non-conductive state).
- terminal J2 is an acoustic signal line JA and, one end is connected to the other end of the connected resistor 33 to a power source V D, terminal J3 is, microphone terminal TJ3 of the jack 14, and multiplexing Connected to data signal line JB.
- the terminal J4 is a control terminal for controlling on and off between the terminals J2 and J3, and in the switch unit 401, between the terminals J2 and J3 according to the signal supplied to the terminal J4, Turn on or off.
- the terminal J4 is connected to the plug detection unit 101 and the pattern detection unit 103, and therefore, the terminals J2 and J3 of the switch unit 401 are connected from the plug detection unit 101 and the pattern detection unit 103. It is turned on or off according to the signal supplied to the terminal J4.
- Coil 402 a multiplexed data signal lines JB, are connected in series between the power source V D, cuts the AC component of the signal flowing from the coil 402 to the power supply V D side.
- the terminal J1 is connected to the connection point between the power supply V D and the coil 402.
- One end of the capacitor 403 is connected to a connection point between the coil 402 and the multiplexed data signal line JB, and the other end of the capacitor 403 is connected to the transmission / reception processing unit 47 and the pattern detection unit 103.
- the capacitor 403 cuts the DC component of the signal flowing from the capacitor 403 to the transmission / reception processing unit 47 side and the pattern detection unit 103 side.
- the switch unit 411 is configured using an analog switch and has terminals P1, P2, P3, and P4.
- the terminals P1 to P4 of the switch unit 411 correspond to the terminals J1 to J4 of the switch unit 401, respectively.
- the switch unit 411 between the terminals P2 and P3 is turned on or off according to the signal supplied to the terminal P4.
- the terminal P4 is connected to the power detection unit 111, and therefore, the terminal P2 and P3 of the switch unit 411 are turned on according to the signal supplied from the power detection unit 111 to the terminal P4. Or turned off.
- the terminal P1 is connected to a connection point between the coil 413 and the LDO 74, and the terminal P2 is connected to the microphone terminal TP3 of the plug 23 and the multiplexed data signal line PB.
- the terminal P3 is connected to the acoustic signal line PA, and the terminal P4 is connected to the power detection unit 111 as described above.
- the capacitor 412 is connected in series between the multiplexed data signal line PB and the transmission processing unit 78 (further, the control unit 75 and the PLL 77), and cuts the DC component of the signal flowing to the transmission processing unit 78 side.
- One end of the coil 413 is connected to a connection point between the microphone terminal TP3 of the plug 23 and the multiplexed data signal line PB, and the other end of the coil 413 is connected to the LDO 74.
- One end of the capacitor 414 is grounded (connected to the ground), and the other end of the capacitor 414 is connected to a connection point between the coil 413 and the LDO 74.
- the AC component of the signal supplied to the LDO 74 is cut from the microphone terminal TP3 of the plug 23 via the coil 413 and the capacitor 414.
- the plug detection unit 101 detects that the plug is inserted into the jack 14.
- the plug detecting unit 101 When the plug detecting unit 101 detects that a plug is inserted into the jack 14, the plug detecting unit 101 supplies a control signal to the terminal J4 of the switch unit 401, thereby turning off between the terminals J2 and J3.
- the transmission / reception processing unit 47 starts transmission of the clock (including the signal) in synchronization with the clock from the clock generation unit 15, and further transmits the master authentication pattern stored in the authentication pattern output unit 102. Start.
- the clock and master authentication pattern transmitted by the transmission / reception processing unit 47 are output from the microphone terminal TJ3 of the jack 14 via the capacitor 403 and the multiplexed data signal line JB.
- the pattern detection unit 103 After starting the transmission of the clock and the master authentication pattern, the pattern detection unit 103 waits for the slave authentication pattern to be transmitted from the plug device having the plug inserted into the jack 14.
- the pattern detection unit 103 detects (recognizes) that the plug device having the plug inserted into the jack 14 is not a compatible device. Then, a control signal is supplied to the terminal J4 of the switch unit 401 so as to turn on between the terminals J2 and J3.
- the microphone terminal TJ3 of the jack 14 is connected to the acoustic signal line JA through the switch unit 401, and the switch unit 401 and the resistor 33 are connected. Is connected to the power source V D via
- the host device 10 corresponds to a plug device having a plug inserted into the jack 14 as described with reference to FIG. 2, for example, a four-pole existing headset having a microphone. Operation (conventional mode operation) when the device is not.
- a slave authentication pattern is transmitted from a plug device having a plug inserted into the jack 14, for example, the plug 23 of the input device 20 that is a corresponding device is inserted into the jack 14 and the input device 20
- the slave authentication pattern is transmitted to the pattern detection unit 103 via the microphone terminal TJ3 of the jack 14, the multiplexed data signal line JB, and the capacitor 403, the pattern detection unit 103 displays the slave authentication pattern.
- the slave authentication pattern is received, it is detected that the plug device having the plug inserted into the jack 14 is a compatible device.
- the pattern detection unit 103 When it is detected that the plug device having the plug inserted into the jack 14 is a corresponding device, the pattern detection unit 103 indicates that the switch 41 described in FIG. 8 has been switched to select the terminal 41B. A corresponding signal (hereinafter also referred to as a corresponding device detection signal) is supplied to the interrupter 46.
- the interrupter 46 supplies the signal processing block 11 that the corresponding device (plug) has been inserted into the jack 14.
- the transmission / reception processing unit 47 sends the ACK signal to the jack 14 via the capacitor 403, the multiplexed data signal line JB, and the microphone terminal TJ3 of the jack 14.
- the input device 20 is transmitted (returned) as a plug device having the inserted plug.
- the transmission / reception processing unit 47 starts receiving multiplexed data transmitted from the input device 20 via the microphone terminal TJ3 of the jack 14, the multiplexed data signal line JB, and the capacitor 403.
- the power detection unit 111 causes the plug 23 to be connected to the jack (jack 14 or an existing jack with four poles). ) Is detected.
- the power detector 111 detects that the plug 23 is inserted into the jack when the voltage at the microphone terminal TP3 of the plug 23 changes to the voltage of the power supply D (close voltage).
- the power detection unit 111 When the power detection unit 111 detects that the plug 23 is inserted into the jack, the power detection unit 111 supplies a control signal to the terminal P4 of the switch unit 411, thereby turning off between the terminals P2 and P3.
- the microphone terminal TP3 of the plug 23 is connected to the LDO 74 via the coil 413.
- the host device 10 by leaving the terminals J2 and J3 of the switch unit 401 turned on, the host device 10 can use an existing headset with four poles having a microphone. It is possible to imitate existing jack devices that are not compatible devices.
- the LDO 74 of the input device 20 Is supplied with power V D via the resistor 33 (of the host device 10), the switch unit 401, the microphone terminal TJ3 of the jack 14, the microphone terminal TP3 of the plug 23 (of the input device 10), and the coil 413. .
- the LDO 74 has sufficient power (voltage),
- the block for transmitting multiplexed data such as the control unit 75 and the transmission processing unit 78 cannot be supplied, and therefore the block for transmitting multiplexed data does not operate.
- the power detection unit 111 detects that the jack device connected to the plug 23 is not a compatible device, and switches the switch unit. By supplying a control signal to the terminal P4 of 411, the terminal P2 and P3 are turned on.
- the microphone terminal T3 of the plug 23 is connected to the acoustic signal line PA via the switch unit 411.
- the input device 20 is an existing smartphone in which the jack device having the jack with the plug 23 inserted as described with reference to FIG. 2 corresponds to, for example, a four-pole existing headset having a microphone. The operation in the case of an existing jack device that is not a compatible device is performed.
- the jack device connected to the input device 20 is the host device 10 which is a corresponding device, as described above, the connection between the terminals J2 and J3 of the switch unit 401 is turned off in the host device 10. Is done.
- the LDO 74 of the input device 20 is connected to the coil 402, the microphone terminal TJ3 of the jack 14, the microphone terminal TP3 of the plug 23, and the coil 413.
- Power supply V D is supplied.
- V D Voltage
- the PLL 77 receives the clock transmitted from the host device 10 via the microphone terminal TP3 of the plug 23, the multiplexed data signal line PB, and the capacitor 412, and starts its operation.
- the PLL 77 enters a so-called locked state, the PLL 77 supplies a clock synchronized with the clock from the transmission / reception processing unit 47 to the transmission processing unit 78 and the like.
- the transmission processing unit 78 starts operation in synchronization with the clock from the PLL 77.
- control unit 75 receives the master authentication pattern transmitted from the host device 10 via the microphone terminal TP 3 of the plug 23, the multiplexed data signal line PB, and the capacitor 412.
- control unit 75 When the control unit 75 receives the master authentication pattern, the control unit 75 detects that the jack device having the jack into which the plug 23 is inserted is a compatible device, and sends a slave authentication pattern from the authentication pattern output unit 112 to the transmission processing unit 78. , For a predetermined time.
- the slave authentication pattern transmitted by the transmission processing unit 78 is output from the microphone terminal TP3 of the plug 23 via the capacitor 412 and the multiplexed data signal line JB.
- the slave authentication pattern output from the microphone terminal TP3 of the plug 23 is received by the pattern detection unit 103 as described above via the microphone terminal TJ3 of the jack 14, the multiplexed data signal line JB, and the capacitor 403.
- the transmission / reception processing unit 47 transmits the ACK signal to the capacitor 403, the multiplexed data signal line JB, and the microphone terminal of the jack 14 as described above. Since the data is transmitted via TJ3, the control unit 75 of the input device 20 causes the ACK signal transmitted via the microphone terminal TJ3 of the jack 14 to be transmitted to the microphone terminal TP3 of the plug 23 and the multiplexed data. The signal is received via the signal line PB and the capacitor 412.
- the transmission processing unit 78 a switch signal from the switch 80, the digital sound signal #i, data read from the register 76 from the ADC 84 i, and multiplexes data read out from the nonvolatile memory 85
- the resulting multiplexed data is transmitted / received via the capacitor 412, the multiplexed data signal line PB, the microphone terminal TP3 of the plug 23, the microphone terminal TJ3 of the jack 14, the multiplexed data signal line JB, and the capacitor 403. Processing to be transmitted to the processing unit 47 is started.
- the multiplexed data transmitted from the transmission processing unit 78 as described above is received by the transmission / reception processing unit 47.
- FIG. 33 is a circuit diagram showing a configuration example of the switch unit 401 of FIG.
- the switch unit 401 includes an FET (Field-Effect-Transistor) switch 431 that is an analog switch.
- FET Field-Effect-Transistor
- the FET switch 431 includes FETs 441 and 442, resistors 443 and 444, and an inverter 445.
- the FET 441 is an nMOS (n-channel Metal Metal Oxide Semiconductor) FET, and its gate is connected to one end of the resistor 443.
- the drain of the FET 441 is connected to the source of the FET 442, and the source of the FET 441 is connected to the drain of the FET 442.
- the FET 442 is a pMOS (p-channel MOS) FET, and its gate is connected to one end of the resistor 444. Note that, as described above, the source of the FET 442 is connected to the drain of the FET 441, and the drain of the FET 442 is connected to the source of the FET 441.
- connection point between the drain of the FET 441 and the source of the FET 442 is connected to the terminal J2, and the connection point between the source of the FET 441 and the drain of the FET 442 is connected to the terminal J3.
- one end of the resistor 443 is connected to the gate of the FET 441, and the other end of the resistor 443 is connected to the terminal J1.
- one end of the resistor 444 is connected to the gate of the FET 442, and the other end of the resistor 444 is grounded.
- the input terminal of the inverter 445 is connected to the connection point between the terminal J4 and the gate of the FET 442 and the resistor 444.
- An output terminal of the inverter 445 is connected to a connection point between the gate of the FET 441 and the resistor 443.
- the FET switch 431 configured as described above operates using the voltage at the terminal J1 as a power source.
- the voltage at the terminal J4 is at the H level
- the H level is applied to the gate of the FET 442 and the gate of the FET 441 is Is applied with an L level via an inverter 445.
- both the FETs 441 and 442 are turned off, and the terminals J2 and J3 are turned off (non-conducting state).
- the L level is applied to the gate of the FET 442
- the H level is applied to the gate of the FET 441 via the inverter 445.
- both the FETs 441 and 442 are turned on, and the terminals J2 and J3 are turned on (conductive state).
- the FET switch 431 can turn on or off between the terminals J2 and J3 according to a signal (control signal) supplied to the terminal J4.
- a protection diode is provided as appropriate for protection from overvoltage (overcurrent).
- the protection diode is not shown in order to avoid making the figure complicated. is there.
- FIG. 34 is a circuit diagram showing a configuration example of the switch unit 401 when a protection diode is provided.
- a diode 451 is disposed on the terminal J2 side between the terminal J1 and the ground
- a diode 452 is disposed on the terminal J3 side between the terminal J1 and the ground
- a diode 452 is disposed between the terminal J2 and the ground.
- 453 is provided between the terminal J3 and the ground
- the diode 454 is provided between the terminals J1 and J2
- the diode 455 is provided between the terminals J1 and J3
- the diode 456 is provided as a protective diode.
- FIG. 35 is a circuit diagram showing a configuration example of the switch unit 411 in FIG.
- the switch unit 411 includes a FET switch 461 that is an analog switch.
- the switch unit 411 also includes a diode 491 and a capacitor 492.
- the FET switch 461 includes FETs 471 and 472, resistors 473 and 474, and an inverter 475, and is configured similarly to the FET switch 431 in FIG.
- the FET 471 is an nMOS FET, and its gate is connected to one end of the resistor 473.
- the drain of the FET 471 is connected to the source of the FET 472 which is a pMOS FET, and the source of the FET 471 is connected to the drain of the FET 472.
- the gate of the FET 472 is connected to the other end of the resistor 474 whose one end is grounded.
- the connection point between the drain of the FET 471 and the source of the FET 472 is connected to the terminal P2, and the connection point between the source of the FET 471 and the drain of the FET 472 is connected to the terminal P3.
- the input terminal of the inverter 475 is connected to the connection point between the terminal P4 and the gate of the FET 472 and the resistor 474.
- An output terminal of the inverter 475 is connected to a connection point between the gate of the FET 471 and the resistor 473.
- the FET switch 461 configured as described above operates using the voltage supplied from the terminal P1 through the diode 491 as a power source.
- the voltage at the terminal P4 is at the H level, The level is applied, and the L level is applied to the gate of the FET 471 via the inverter 475.
- both the FETs 471 and 472 are turned off, and the terminals P2 and P3 are turned off (non-conducting state).
- the L level is applied to the gate of the FET 472, and the H level is applied to the gate of the FET 471 via the inverter 475.
- both the FETs 471 and 472 are turned on, and the terminals P2 and P3 are turned on (conductive state).
- the FET switch 461 can turn on or off between the terminals P2 and P3 according to a signal (control signal) supplied to the terminal P4.
- the switch unit 411 includes a diode 491 and a capacitor 492 in addition to the FET switch 461.
- the anode of the diode 491 is connected to the terminal P1, and the cathode of the diode 491 is connected to the other end of the resistor 473 whose one end is connected to the gate of the FET 471.
- the cathode of the diode 491 is also connected to a capacitor 492 whose one end is grounded.
- the reason why the switch unit 411 of the input device 20 includes the above-described diode 491 and capacitor 492 in addition to the FET switch 461 is as follows.
- connection point PS is short-circuited to the ground when the switch 80 is operated
- switch 80 is operated,
- the terminal P3 of 411 is connected to the ground at approximately 0 ohm through the acoustic signal line PA, the connection point PS, and the switch 80 connected to the connection point PS.
- the switch unit 411 does not have the diode 491 and the capacitor 492, and the terminal P1 is directly connected to the resistor 473 of the FET switch 461, the terminal P1 of the switch unit 411 is input. Since it is connected to the microphone terminal TP3 of the plug 23 via the coil 413 of the device 20 (FIG. 32), the FET switch 461 is connected from the host device 10 via the microphone terminal TP3 of the plug 23 and the coil 413. The signal supplied to the terminal P1 of the switch unit 411 operates as a power source.
- the FET 471 is turned off (opened), making it difficult to keep the terminals P2 and P3 of the switch unit 411 on, and the terminals P2 and P3 are turned off. become.
- the operation of the switch 80 turns off between the terminals P ⁇ b> 2 and P ⁇ b> 3 of the switch unit 411 and the existing device connected to the input device 20 is connected. in the jack device, and switches the signal of the switch 80, to prevent it becomes impossible to transmit a sound signal of the microphone 81 0, the switch unit 411, diode 491, and capacitor 492 is provided.
- a circuit including a diode 491 having an anode connected to the terminal P1 and a capacitor 492 having one end grounded and the other end connected to the cathode of the diode 491 supplies power to the FET switch 461. Configure the circuit.
- the power supply circuit composed of the diode 491 and the capacitor 492 is a separate power supply from the LDO 74 that supplies power to the control unit 75 and the transmission processing unit 78.
- the signal supplied from the terminal P1 of the switch unit 411 is rectified in the diode 491, and the capacitor 492 is charged by the rectified signal. Then, power is supplied to the FET switch 461 by the charged capacitor 492.
- the capacitor 492 causes the gate voltage of the nMOS FET 471, and hence between the gate and the source.
- the voltage V GS can be maintained and the FET 471 can be prevented from being turned off.
- the current consumed by the switch unit 411 is the reverse bias current of the diode 491, the leakage current of the capacitor 492, and the gate current of the FET 471. Is very small.
- the switch unit 401 (FIG. 33) of the host device 10 since the voltage between the gate and the source of the FET 441 cannot be maintained by the operation of the switch 80, the power supply composed of the diode 491 and the capacitor 492 There is no need to provide a separate power source such as a circuit.
- the switch unit 401 (FIG. 33) can also be provided with a separate power source such as a power supply circuit including a diode 491 and a capacitor 492, similarly to the switch unit 411 (FIG. 35).
- a separate power source such as a power supply circuit including a diode 491 and a capacitor 492, similarly to the switch unit 411 (FIG. 35).
- the diode 491 also has a function of preventing the backflow of current to the terminal P1.
- FIG. 35 as in the case of FIG. 33, the protection diode is not shown in order to avoid complication of the drawing.
- FIG. 36 is a circuit diagram showing a configuration example of the switch unit 411 when a protection diode is provided.
- a diode 481 is provided on the terminal P2 side between the terminal P1 and the ground
- a diode 482 is provided on the terminal P3 side between the terminal P1 and the ground
- a diode is provided between the terminal P2 and the ground.
- 483 is provided between the terminal P3 and the ground
- the diode 484 is provided between the terminals P1 and P2
- the diode 485 is provided between the terminals P1 and P3
- the diode 486 is provided as a protective diode.
- the above-described processing (a part thereof) can be performed by hardware or software as necessary.
- a program constituting the software is installed in a computer or the like.
- FIG. 37 shows a configuration example of an embodiment of a computer in which a program for executing the above-described processing is installed.
- the program can be recorded in advance in a hard disk 305 or ROM 303 as a recording medium built in the computer.
- the program can be stored (recorded) in a removable recording medium 311.
- a removable recording medium 311 can be provided as so-called package software.
- examples of the removable recording medium 311 include a flexible disk, a CD-ROM (Compact Disc Read Only Memory), an MO (Magneto Optical) disc, a DVD (Digital Versatile Disc), a magnetic disc, a semiconductor memory, and the like.
- the program can be installed in the computer from the removable recording medium 311 as described above, or can be downloaded to the computer via the communication network or the broadcast network and installed in the built-in hard disk 305. That is, the program is transferred from a download site to a computer wirelessly via a digital satellite broadcasting artificial satellite, or wired to a computer via a network such as a LAN (Local Area Network) or the Internet. be able to.
- a network such as a LAN (Local Area Network) or the Internet.
- the computer includes a CPU (Central Processing Unit) 302, and an input / output interface 310 is connected to the CPU 302 via the bus 301.
- a CPU Central Processing Unit
- an input / output interface 310 is connected to the CPU 302 via the bus 301.
- the CPU 302 executes a program stored in a ROM (Read Only Memory) 303 accordingly. .
- the CPU 302 loads a program stored in the hard disk 305 to a RAM (Random Access Memory) 304 and executes it.
- the CPU 302 performs processing according to the flowchart described above or processing performed by the configuration of the block diagram described above. Then, the CPU 302 causes the processing result to be output from the output unit 306 or transmitted from the communication unit 308 via the input / output interface 310, or recorded on the hard disk 305, for example, as necessary.
- the input unit 307 includes a keyboard, a mouse, a microphone, and the like.
- the output unit 306 includes an LCD (Liquid Crystal Display), a speaker, and the like.
- the processing performed by the computer according to the program does not necessarily have to be performed in chronological order in the order described as the flowchart. That is, the processing performed by the computer according to the program includes processing executed in parallel or individually (for example, parallel processing or object processing).
- the program may be processed by one computer (processor), or may be distributedly processed by a plurality of computers. Furthermore, the program may be transferred to a remote computer and executed.
- the system means a set of a plurality of components (devices, modules (parts), etc.), and it does not matter whether all the components are in the same housing. Accordingly, a plurality of devices housed in separate housings and connected via a network and a single device housing a plurality of modules in one housing are all systems. .
- the present technology can take a cloud computing configuration in which one function is shared by a plurality of devices via a network and is jointly processed.
- each step described in the above flowchart can be executed by one device or can be shared by a plurality of devices.
- the plurality of processes included in the one step can be executed by being shared by a plurality of apparatuses in addition to being executed by one apparatus.
- this technique can take the following structures.
- a storage unit for storing device information related to the input device; The input device according to ⁇ 1>, wherein the multiplexed data also includes the device information.
- the input device according to any one of ⁇ 1> to ⁇ 3>, further including a sound output unit that outputs sound corresponding to the sound signal transmitted from the jack device.
- the conversion unit is a microphone that converts sound into an acoustic signal;
- the plug is A ground terminal connected to the ground, two acoustic signal terminals that receive an input of a two-channel acoustic signal corresponding to the sound output from the acoustic output unit, and A plug having one microphone terminal for outputting an acoustic signal output from a predetermined one of the plurality of microphones as the plurality of conversion units to the jack device;
- the input device according to ⁇ 4>, wherein the transmission processing unit transmits the multiplexed data from the microphone terminal.
- ⁇ 6> Select one of an acoustic signal line for transmitting an acoustic signal output from the predetermined microphone and a multiplexed data signal line for transmitting the multiplexed data output from the transmission processing unit.
- the input device according to ⁇ 5> further including a selection unit connected to the microphone terminal.
- the detector is When a predetermined signal is received via the microphone terminal, the jack device is detected as the corresponding device, The selection unit that selects the acoustic signal line is switched to select the multiplexed data signal line, The input device according to ⁇ 6>, wherein the transmission processing unit transmits the multiplexed data via the multiplexed data signal line and the microphone terminal.
- the selection unit that selects the acoustic signal line is switched to select the multiplexed data signal line
- the detection unit detects that the jack device is the corresponding device when a predetermined signal is received via the microphone terminal and the multiplexed data signal line;
- the input device according to ⁇ 6> wherein the transmission processing unit transmits the multiplexed data via the multiplexed data signal line and the microphone terminal.
- a plug inserted into the jack of a jack device having a jack An input device having a plurality of conversion units that convert physical quantities into electrical signals, Detecting whether the jack device is a compatible device capable of handling multiplexed data obtained by multiplexing the electrical signals output from the plurality of converters;
- a transmission method of the input device comprising: transmitting the multiplexed data via the plug when the jack device is the corresponding device.
- a host device comprising: a reception processing unit that receives the multiplexed data transmitted from the plug device that is the corresponding device via the jack when the plug device is the corresponding device.
- the multiplexed data also includes device information regarding the plug device that is the corresponding device, The host device according to ⁇ 10>, further including a signal processing unit that performs signal processing according to the device information.
- ⁇ 12> The host device according to ⁇ 10> or ⁇ 11>, wherein power is supplied to the plug device.
- the plug device that is the corresponding device has the plurality of conversion units,
- the conversion unit is a microphone that converts sound into an acoustic signal;
- the jack A ground terminal connected to the ground, and two acoustic signal terminals for outputting two-channel acoustic signals output from the acoustic interface;
- One microphone terminal for receiving an input of an acoustic signal output from a predetermined one of the plurality of microphones as the plurality of conversion units,
- the host device according to ⁇ 13>, wherein the reception processing unit receives the multiplexed data via the microphone terminal.
- ⁇ 15> Select one of an acoustic signal line for receiving an acoustic signal output from the predetermined microphone and a multiplexed data signal line for receiving the multiplexed data, and connect to the microphone terminal
- the host device according to ⁇ 14> further including a selection unit.
- the detector is When a predetermined signal is received via the microphone terminal, the plug device is detected as the corresponding device, The selection unit that selects the acoustic signal line is switched to select the multiplexed data signal line, The host device according to ⁇ 15>, wherein the reception processing unit receives the multiplexed data via the microphone terminal and the multiplexed data signal line.
- the selection unit that selects the acoustic signal line is switched to select the multiplexed data signal line
- the detection unit detects that the plug device is the corresponding device when a predetermined signal is received via the microphone terminal and the multiplexed data signal line;
- the host device according to ⁇ 15>, wherein the reception processing unit receives the multiplexed data via the microphone terminal and the multiplexed data signal line.
- the host device receiving method includes the step of receiving, via the jack, the multiplexed data transmitted from the plug device that is the compatible device.
- an input device having: a transmission processing unit that transmits the multiplexed data via the plug; A jack into which the plug of the plug device having a plug is inserted; Another detection unit that detects whether the plug device is the corresponding device;
- a signal including: a host device having: a reception processing unit that receives the multiplexed data transmitted from the plug device that is the compatible device via the jack Processing system.
- An input device having a plurality of conversion units that convert physical quantities into electrical signals, Detecting whether the jack device is a compatible device capable of handling multiplexed data obtained by multiplexing the electrical signals output from the plurality of converters;
- the jack device is the corresponding device, transmitting the multiplexed data through the plug;
- a host device having a jack into which the plug of the plug device having a plug is inserted; Detecting whether the plug device is the corresponding device; Receiving the multiplexed data transmitted from the plug device, which is the corresponding device, when the plug device is the corresponding device, via the jack.
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Abstract
Description
・・・(1)
・・・(2)
・・・(3)
・・・(4)
・・・(5)
・・・(6)
ジャックを有するジャックデバイスの前記ジャックに挿入されるプラグと、
物理量を電気信号に変換する複数の変換部と、
前記ジャックデバイスが、前記複数の変換部が出力する前記電気信号を多重化した多重化データを扱うことができる対応デバイスであるかどうかを検出する検出部と、
前記ジャックデバイスが前記対応デバイスである場合に、前記多重化データを、前記プラグを介して送信する送信処理部と
を備える入力デバイス。
<2>
前記入力デバイスに関するデバイス情報を記憶する記憶部をさらに有し、
前記多重化データは、前記デバイス情報をも含む
<1>に記載の入力デバイス。
<3>
前記ジャックデバイスから電源の供給を受けて動作する
<1>又は<2>に記載の入力デバイス。
<4>
前記ジャックデバイスから送信されてくる音響信号に対応する音響を出力する音響出力部をさらに備える
<1>ないし<3>のいずれかに記載の入力デバイス。
<5>
前記変換部は、音響を音響信号に変換するマイクであり、
前記プラグは、
グランドに接続されるグランド端子と
前記音響出力部から出力する音響に対応する2チャンネルの音響信号の入力を受ける2つの音響信号端子と、
前記複数の変換部である複数のマイクのうちの所定の1つのマイクが出力する音響信号を前記ジャックデバイスに出力するための1つのマイク端子と
を有するプラグであり、
前記送信処理部は、前記多重化データを、前記マイク端子から送信する
<4>に記載の入力デバイス。
<6>
前記所定の1つのマイクが出力する音響信号を送信するための音響信号線、及び、前記送信処理部が出力する前記多重化データを送信するための多重化データ信号線のうちの一方を選択し、前記マイク端子に接続する選択部をさらに備える
<5>に記載の入力デバイス。
<7>
前記検出部は、
前記マイク端子を介して、所定の信号を受信した場合に、前記ジャックデバイスが前記対応デバイスであることを検出し、
前記音響信号線を選択している選択部を、前記多重化データ信号線を選択するように切り替え、
前記送信処理部は、前記多重化データを、前記多重化データ信号線、及び、前記マイク端子を介して送信する
<6>に記載の入力デバイス。
<8>
前記マイク端子の信号に、所定の変化が生じた場合に、前記音響信号線を選択している選択部が、前記多重化データ信号線を選択するように切り替えられ、
前記検出部は、前記マイク端子、及び、前記多重化データ信号線を介して、所定の信号を受信した場合に、前記ジャックデバイスが前記対応デバイスであることを検出し、
前記送信処理部は、前記多重化データを、前記多重化データ信号線、及び、前記マイク端子を介して送信する
<6>に記載の入力デバイス。
<9>
ジャックを有するジャックデバイスの前記ジャックに挿入されるプラグと、
物理量を電気信号に変換する複数の変換部と
を有する入力デバイスが、
前記ジャックデバイスが、前記複数の変換部が出力する前記電気信号を多重化した多重化データを扱うことができる対応デバイスであるかどうかを検出し、
前記ジャックデバイスが前記対応デバイスである場合に、前記多重化データを、前記プラグを介して送信する
ステップを含む前記入力デバイスの送信方法。
<10>
プラグを有するプラグデバイスの前記プラグが挿入されるジャックと、
前記プラグデバイスが、物理量を電気信号に変換する複数の変換部が出力する前記電気信号を多重化した多重化データを扱うことができる対応デバイスであるかどうかを検出する検出部と、
前記プラグデバイスが前記対応デバイスである場合に、前記対応デバイスである前記プラグデバイスから送信されてくる前記多重化データを、前記ジャックを介して受信する受信処理部と
を備えるホストデバイス。
<11>
前記多重化データは、前記対応デバイスである前記プラグデバイスに関するデバイス情報をも含み、
前記デバイス情報に応じた信号処理を行う信号処理部をさらに備える
<10>に記載のホストデバイス。
<12>
前記プラグデバイスに電源を供給する
<10>又は<11>に記載のホストデバイス。
<13>
前記プラグデバイスに、音響信号を送信する音響インターフェースをさらに備える
<10>ないし<12>のいずれかに記載のホストデバイス。
<14>
前記対応デバイスである前記プラグデバイスは、前記複数の変換部を有し、
前記変換部は、音響を音響信号に変換するマイクであり、
前記ジャックは、
グランドに接続されるグランド端子と
前記音響インターフェースから出力される2チャンネルの音響信号を出力する2つの音響信号端子と、
前記複数の変換部である複数のマイクのうちの所定の1つのマイクが出力する音響信号の入力を受けるための1つのマイク端子と
を有するジャックであり、
前記受信処理部は、前記多重化データを、前記マイク端子を介して受信する
<13>に記載のホストデバイス。
<15>
前記所定の1つのマイクが出力する音響信号を受信するための音響信号線、及び、前記多重化データを受信するための多重化データ信号線のうちの一方を選択し、前記マイク端子に接続する選択部をさらに備える
<14>に記載のホストデバイス。
<16>
前記検出部は、
前記マイク端子を介して、所定の信号を受信した場合に、前記プラグデバイスが前記対応デバイスであることを検出し、
前記音響信号線を選択している選択部を、前記多重化データ信号線を選択するように切り替え、
前記受信処理部は、前記多重化データを、前記マイク端子、及び、前記多重化データ信号線を介して受信する
<15>に記載のホストデバイス。
<17>
前記ジャックに、前記プラグが挿入された場合に、前記音響信号線を選択している選択部が、前記多重化データ信号線を選択するように切り替えられ、
前記検出部は、前記マイク端子、及び、前記多重化データ信号線を介して、所定の信号を受信した場合に、前記プラグデバイスが前記対応デバイスであることを検出し、
前記受信処理部は、前記多重化データを、前記マイク端子、及び、前記多重化データ信号線を介して受信する
<15>に記載のホストデバイス。
<18>
プラグを有するプラグデバイスの前記プラグが挿入されるジャックを有するホストデバイスが、
前記プラグデバイスが、物理量を電気信号に変換する複数の変換部が出力する前記電気信号を多重化した多重化データを扱うことができる対応デバイスであるかどうかを検出し、
前記プラグデバイスが前記対応デバイスである場合に、前記対応デバイスである前記プラグデバイスから送信されてくる前記多重化データを、前記ジャックを介して受信する
ステップを含む前記ホストデバイスの受信方法。
<19>
ジャックを有するジャックデバイスの前記ジャックに挿入されるプラグと、
物理量を電気信号に変換する複数の変換部と、
前記ジャックデバイスが、前記複数の変換部が出力する前記電気信号を多重化した多重化データを扱うことができる対応デバイスであるかどうかを検出する検出部と、
前記ジャックデバイスが前記対応デバイスである場合に、前記多重化データを、前記プラグを介して送信する送信処理部と
を有する入力デバイスと、
プラグを有するプラグデバイスの前記プラグが挿入されるジャックと、
前記プラグデバイスが、前記対応デバイスであるかどうかを検出する他の検出部と、
前記プラグデバイスが前記対応デバイスである場合に、前記対応デバイスである前記プラグデバイスから送信されてくる前記多重化データを、前記ジャックを介して受信する受信処理部と
を有するホストデバイスと
を備える信号処理システム。
<20>
ジャックを有するジャックデバイスの前記ジャックに挿入されるプラグと、
物理量を電気信号に変換する複数の変換部と
を有する入力デバイスが、
前記ジャックデバイスが、前記複数の変換部が出力する前記電気信号を多重化した多重化データを扱うことができる対応デバイスであるかどうかを検出し、
前記ジャックデバイスが前記対応デバイスである場合に、前記多重化データを、前記プラグを介して送信する
ステップと、
プラグを有するプラグデバイスの前記プラグが挿入されるジャックを有するホストデバイスが、
前記プラグデバイスが、前記対応デバイスであるかどうかを検出し、
前記プラグデバイスが前記対応デバイスである場合に、前記対応デバイスである前記プラグデバイスから送信されてくる前記多重化データを、前記ジャックを介して受信する
ステップと
を含む送受信方法。
Claims (20)
- ジャックを有するジャックデバイスの前記ジャックに挿入されるプラグと、
物理量を電気信号に変換する複数の変換部と、
前記ジャックデバイスが、前記複数の変換部が出力する前記電気信号を多重化した多重化データを扱うことができる対応デバイスであるかどうかを検出する検出部と、
前記ジャックデバイスが前記対応デバイスである場合に、前記多重化データを、前記プラグを介して送信する送信処理部と
を備える入力デバイス。 - 前記入力デバイスに関するデバイス情報を記憶する記憶部をさらに有し、
前記多重化データは、前記デバイス情報をも含む
請求項1に記載の入力デバイス。 - 前記ジャックデバイスから電源の供給を受けて動作する
請求項2に記載の入力デバイス。 - 前記ジャックデバイスから送信されてくる音響信号に対応する音響を出力する音響出力部をさらに備える
請求項3に記載の入力デバイス。 - 前記変換部は、音響を音響信号に変換するマイクであり、
前記プラグは、
グランドに接続されるグランド端子と
前記音響出力部から出力する音響に対応する2チャンネルの音響信号の入力を受ける2つの音響信号端子と、
前記複数の変換部である複数のマイクのうちの所定の1つのマイクが出力する音響信号を前記ジャックデバイスに出力するための1つのマイク端子と
を有するプラグであり、
前記送信処理部は、前記多重化データを、前記マイク端子から送信する
請求項4に記載の入力デバイス。 - 前記所定の1つのマイクが出力する音響信号を送信するための音響信号線、及び、前記送信処理部が出力する前記多重化データを送信するための多重化データ信号線のうちの一方を選択し、前記マイク端子に接続する選択部をさらに備える
請求項5に記載の入力デバイス。 - 前記検出部は、
前記マイク端子を介して、所定の信号を受信した場合に、前記ジャックデバイスが前記対応デバイスであることを検出し、
前記音響信号線を選択している選択部を、前記多重化データ信号線を選択するように切り替え、
前記送信処理部は、前記多重化データを、前記多重化データ信号線、及び、前記マイク端子を介して送信する
請求項6に記載の入力デバイス。 - 前記マイク端子の信号に、所定の変化が生じた場合に、前記音響信号線を選択している選択部が、前記多重化データ信号線を選択するように切り替えられ、
前記検出部は、前記マイク端子、及び、前記多重化データ信号線を介して、所定の信号を受信した場合に、前記ジャックデバイスが前記対応デバイスであることを検出し、
前記送信処理部は、前記多重化データを、前記多重化データ信号線、及び、前記マイク端子を介して送信する
請求項6に記載の入力デバイス。 - ジャックを有するジャックデバイスの前記ジャックに挿入されるプラグと、
物理量を電気信号に変換する複数の変換部と
を有する入力デバイスが、
前記ジャックデバイスが、前記複数の変換部が出力する前記電気信号を多重化した多重化データを扱うことができる対応デバイスであるかどうかを検出し、
前記ジャックデバイスが前記対応デバイスである場合に、前記多重化データを、前記プラグを介して送信する
ステップを含む前記入力デバイスの送信方法。 - プラグを有するプラグデバイスの前記プラグが挿入されるジャックと、
前記プラグデバイスが、物理量を電気信号に変換する複数の変換部が出力する前記電気信号を多重化した多重化データを扱うことができる対応デバイスであるかどうかを検出する検出部と、
前記プラグデバイスが前記対応デバイスである場合に、前記対応デバイスである前記プラグデバイスから送信されてくる前記多重化データを、前記ジャックを介して受信する受信処理部と
を備えるホストデバイス。 - 前記多重化データは、前記対応デバイスである前記プラグデバイスに関するデバイス情報をも含み、
前記デバイス情報に応じた信号処理を行う信号処理部をさらに備える
請求項10に記載のホストデバイス。 - 前記プラグデバイスに電源を供給する
請求項11に記載のホストデバイス。 - 前記プラグデバイスに、音響信号を送信する音響インターフェースをさらに備える
請求項12に記載のホストデバイス。 - 前記対応デバイスである前記プラグデバイスは、前記複数の変換部を有し、
前記変換部は、音響を音響信号に変換するマイクであり、
前記ジャックは、
グランドに接続されるグランド端子と
前記音響インターフェースから出力される2チャンネルの音響信号を出力する2つの音響信号端子と、
前記複数の変換部である複数のマイクのうちの所定の1つのマイクが出力する音響信号の入力を受けるための1つのマイク端子と
を有するジャックであり、
前記受信処理部は、前記多重化データを、前記マイク端子を介して受信する
請求項13に記載のホストデバイス。 - 前記所定の1つのマイクが出力する音響信号を受信するための音響信号線、及び、前記多重化データを受信するための多重化データ信号線のうちの一方を選択し、前記マイク端子に接続する選択部をさらに備える
請求項14に記載のホストデバイス。 - 前記検出部は、
前記マイク端子を介して、所定の信号を受信した場合に、前記プラグデバイスが前記対応デバイスであることを検出し、
前記音響信号線を選択している選択部を、前記多重化データ信号線を選択するように切り替え、
前記受信処理部は、前記多重化データを、前記マイク端子、及び、前記多重化データ信号線を介して受信する
請求項15に記載のホストデバイス。 - 前記ジャックに、前記プラグが挿入された場合に、前記音響信号線を選択している選択部が、前記多重化データ信号線を選択するように切り替えられ、
前記検出部は、前記マイク端子、及び、前記多重化データ信号線を介して、所定の信号を受信した場合に、前記プラグデバイスが前記対応デバイスであることを検出し、
前記受信処理部は、前記多重化データを、前記マイク端子、及び、前記多重化データ信号線を介して受信する
請求項15に記載のホストデバイス。 - プラグを有するプラグデバイスの前記プラグが挿入されるジャックを有するホストデバイスが、
前記プラグデバイスが、物理量を電気信号に変換する複数の変換部が出力する前記電気信号を多重化した多重化データを扱うことができる対応デバイスであるかどうかを検出し、
前記プラグデバイスが前記対応デバイスである場合に、前記対応デバイスである前記プラグデバイスから送信されてくる前記多重化データを、前記ジャックを介して受信する
ステップを含む前記ホストデバイスの受信方法。 - ジャックを有するジャックデバイスの前記ジャックに挿入されるプラグと、
物理量を電気信号に変換する複数の変換部と、
前記ジャックデバイスが、前記複数の変換部が出力する前記電気信号を多重化した多重化データを扱うことができる対応デバイスであるかどうかを検出する検出部と、
前記ジャックデバイスが前記対応デバイスである場合に、前記多重化データを、前記プラグを介して送信する送信処理部と
を有する入力デバイスと、
プラグを有するプラグデバイスの前記プラグが挿入されるジャックと、
前記プラグデバイスが、前記対応デバイスであるかどうかを検出する他の検出部と、
前記プラグデバイスが前記対応デバイスである場合に、前記対応デバイスである前記プラグデバイスから送信されてくる前記多重化データを、前記ジャックを介して受信する受信処理部と
を有するホストデバイスと
を備える信号処理システム。 - ジャックを有するジャックデバイスの前記ジャックに挿入されるプラグと、
物理量を電気信号に変換する複数の変換部と
を有する入力デバイスが、
前記ジャックデバイスが、前記複数の変換部が出力する前記電気信号を多重化した多重化データを扱うことができる対応デバイスであるかどうかを検出し、
前記ジャックデバイスが前記対応デバイスである場合に、前記多重化データを、前記プラグを介して送信する
ステップと、
プラグを有するプラグデバイスの前記プラグが挿入されるジャックを有するホストデバイスが、
前記プラグデバイスが、前記対応デバイスであるかどうかを検出し、
前記プラグデバイスが前記対応デバイスである場合に、前記対応デバイスである前記プラグデバイスから送信されてくる前記多重化データを、前記ジャックを介して受信する
ステップと
を含む送受信方法。
Priority Applications (6)
Application Number | Priority Date | Filing Date | Title |
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EP14807051.9A EP3007462A4 (en) | 2013-06-07 | 2014-05-26 | Input device and transmission method; host device and reception method; and signal processing system and transmission/reception method |
KR1020157032828A KR20160018488A (ko) | 2013-06-07 | 2014-05-26 | 입력 디바이스 및 송신 방법, 호스트 디바이스 및 수신 방법, 그리고 신호 처리 시스템 및 송수신 방법 |
JP2015521397A JP6314977B2 (ja) | 2013-06-07 | 2014-05-26 | 入力デバイス及び送信方法、ホストデバイス及び受信方法、並びに、信号処理システム及び送受信方法 |
CN201480031321.6A CN105247887A (zh) | 2013-06-07 | 2014-05-26 | 输入装置和传送方法、主机装置和接收方法以及信号处理系统和收发方法 |
US14/893,741 US20160127815A1 (en) | 2013-06-07 | 2014-05-26 | Input device and transmitting method, host device and receiving method, and signal processing system and transceiving method |
US16/008,571 US20180295435A1 (en) | 2013-06-07 | 2018-06-14 | Input device and transmitting method, host device and receiving method, and signal processing system and transceiving method |
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US20180295435A1 (en) | 2018-10-11 |
JPWO2014196399A1 (ja) | 2017-02-23 |
TW201513680A (zh) | 2015-04-01 |
KR20160018488A (ko) | 2016-02-17 |
JP6314977B2 (ja) | 2018-04-25 |
CN105247887A (zh) | 2016-01-13 |
EP3007462A4 (en) | 2017-05-03 |
EP3007462A1 (en) | 2016-04-13 |
US20160127815A1 (en) | 2016-05-05 |
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