Patent Grant
11900905
The present invention relates to a signal output device that generates a signal based on vibration applied to a drumhead.
In an electronic drum or a muffled acoustic drum, a sound is output from a sound source based on vibration due to a beat applied to a head. A drum trigger including a sensor such as a piezoelectric sensor is installed on the head, and vibration to be applied to the head is sensed by the drum trigger. For example, Japanese laid-open patent publication No. 2007-171233 discloses an electric percussion instrument in which a plurality of vibration pickups are provided on a resonance plate mounted on an attachment section to the percussion instrument to detect vibration applied to the percussion instrument. Japanese laid-open patent publication No. 2010-134341 discloses an electric percussion instrument in which a plurality of vibration pickups are provided on a metal plate provided with an attachment arm. Japanese laid-open patent publication No. 2012-208487 discloses a sheet-shaped piezoelectric sensor having flexibility contacting a drumhead of a percussion instrument.
A signal output device according to an aspect of the present invention includes a housing, a fastener that attaches the housing to an object that includes a portion to be struck, an arm section attached to the housing, an extension section extending from the arm section and configured to contact the portion to be struck, a first sensor that detects vibration transmitted to the arm section and outputs a vibration signal representing the vibration, a second sensor provided on the housing and that detects vibration transmitted to the housing, and output terminal that outputs the vibration detected by at least one of the first sensor or the second sensor.
A signal output device according to an aspect of the present invention includes a housing, a fastener that attaches the housing to an object that includes a portion to be struck, an arm section attached to the housing and configured to be rotatable with respect to the housing about a rotation axis, an extension section extending from the arm section and configured to contact the portion to be struck, and a sensor that detects vibration transmitted to the arm section and outputs a vibration signal representing the vibration, in which the extension extends substantially at a right angle to the rotation axis.
A signal output device according to an aspect of the present invention includes a housing, a fastener that attaches the housing to an object that includes a portion to be struck, an arm section attached to the housing, an extension section extending from the arm section and configured to contact the portion to be struck, and a first sensor that detects vibration transmitted to the arm section and outputs a vibration signal representing the vibration, in which the arm section is configured to be extendable and retractable with respect to the housing.
A drum trigger capable of more efficiently detecting vibration applied to a percussion instrument has been required.
According to the present invention, a signal output device that more efficiently detects vibration applied to a drumhead and generates a signal corresponding to the detected vibration is provided.
A signal output device according to an embodiment of the present invention will be described in detail below with reference to the drawings. Embodiments described below are respectively examples of embodiments of the present invention, and the present invention is not construed as being limited to the embodiments. In the drawings referred to in the embodiments, identical sections or units or sections or units having similar functions are respectively assigned identical or similar reference signs (numerals only followed by A, B, etc.), and its repetitive description may be omitted. A dimensional ratio (a ratio among components, a ratio between vertical and horizontal height directions, etc.) in the drawings may differ from an actual ratio for convenience of illustration, or some of components may be omitted from the drawings.
The outline of a signal output device according to a first embodiment of the present invention will be described. In this example, the signal output device is used to be attached to a drum set, and detects vibration to be applied to a head to convert the vibration into a vibration signal and output the vibration signal. The vibration signal output from the signal output device represents vibration applied to the head. The vibration signal functions as a trigger indicating that vibration has been applied to the head.
A housing 150 is arranged on the front surface side of the signal output device 10. The housing 150 is formed of a material capable of protecting each of portions inside thereof even if accidentally struck by a drum stick by a player, e.g., a metal such as stainless or plastic. The housing 150 is provided with an arm section 160 extending from the housing 150. The arm section 160 is attached to the housing 150 by an attachment section, descried below. The arm section 160 extends toward the drumhead 815 of the bass drum 810 with respect to the rim 818.
Referring to
The control device 50 is installed on a high-hat stand 850 in an example illustrated in
The signal output device 10 and the control device 50 are connected to each other by wire using a cable or the like in the present embodiment. However, the connection between the signal output device 10 and the control device 50 is not limited to wired connection, but the signal output device 10 and the control device 50 may be wirelessly connected to each other. Connection between the control device 50 and the sound radiation device may also be wired connection or wireless connection.
Then, a specific structure of the signal output device 10 will be described.
The housing 150 includes an upper region 151, a lower region 153, an intermediate region 155, a front region 157, a side region 158, and a back region 159. The regions are directly or indirectly connected to one another, and a positional relationship thereamong is fixed. The upper region 151 corresponds to a region arranged on the upper surface side of the housing 150 and a region above a position where the rim 818 is attached. The lower region 153 corresponds to a region arranged on the lower surface side of the housing 150 and a region below the position where the rim 818 is attached. The intermediate region 155 connects the front region 157 and the lower region 153 to each other. In the intermediate region 155, a recessed region 188 is provided. The recessed region 188 has an opening on the side of the lower region 153. The rim 818 is inserted into the recessed region 188 from the opening (from the back surface side).
The front region 157 corresponds to a region on the front surface side of the housing 150. The back region 159 corresponds to a region on the back surface side of the housing 150, and connects the upper region 151 and the lower region 153 to each other. The side region 158 connects the upper region 151, the lower region 153, the intermediate region 155, the front region 157, and the back region 159 to one another on the respective side surface sides of the regions.
The arm section 160 is attached to the front region 157 by an attachment section 170. For example, the attachment section 170 is a screw. A nut may be embedded in the front region 157. As illustrated in
The extension section 161 contacts the drumhead 815 of the bass drum 810. At this time, an angle θ formed between an extension direction of the extension section 161 and the drumhead 815 is preferably a substantially right angle. The vibration applied to the drumhead 815 of the bass drum 810 is transmitted to the arm section 160 through the extension section 161. The sensor 300 (300-1) provided on the arm section 160 detects the vibration transmitted to the arm section 160.
The back region 159 is provided with a fixing screw (fastener) 401. When the fixing screw 401 is rotated, a part of a shaft of the fixing screw 401 protrudes toward the intermediate region 155. The rim 818 inserted into the recessed region 188 is sandwiched and fixed between the part of the shaft of the fixing screw 401 and the housing 150. As a result, the housing 150 is fixed to the rim 818.
The sensor 300 (300-1) is arranged on the arm section 160 in the present embodiment. As described above, the vibration in the bass drum 810 is transmitted to the sensor 300 (300-1) via the extension section 161 and the arm section 160. The sensor 300 (300-1) detects the transmitted vibration, and outputs a vibration signal corresponding to the detected vibration. The vibration signal represents the timing and the magnitude of the vibration detected by the sensor 300 (300-1). The vibration signal may be waveform data representing the timing and the magnitude of the detected vibration. The vibration signal may be amplified by an amplification circuit not illustrated and output.
In the present embodiment, an example in which the sensor 300 (300-1) is provided on the arm section 160 is described. However, the sensor 300 (300-1) may be arranged on the extension section 161 or the side region 158, the intermediate region 155, or the lower region 153 of the housing 150. The sensor 300 (300-1) may be arranged within the housing 150. The number of sensors 300 (300-1) is not limited to one. Two or more sensors 300 may be provided. If a plurality of sensors 300 are provided, the plurality of sensors 300 may be arranged at the same position or may be respectively arranged at different positions. If two sensors are used, for example, the one sensor 300 (300-1) may be arranged on the arm section 160, and the other sensor 300 (300-2) may be arranged on/in the housing 150. The other sensor 300 (300-2) may detect vibration to be transmitted through the arm section 160. The other sensor 300 (300-2) may detect vibration to be transmitted to the housing 150 from a hoop of the bass drum 810 via the recessed region 188. In
In the present embodiment, the arm section 160 attached to the housing 150 is detachable.
The arm section 160 is provided with a protrusion section 601 and a hole 603 into which the attachment section 170 is to be inserted. The front region 157 of the housing 150 is provided with an opening 605 and a hole 607 into which the attachment section 170 is to be inserted. A nut is embedded in the hole 607. When the arm section 160 is attached to the housing 150, the protrusion section 601 provided in the arm section 160 is inserted into the opening 605 provided in the front region 157 of the housing 150. The attachment section 170 is inserted into the hole 603 and the hole 607, and the attachment section 170 is rotated, to screw and fix the arm section 160 to the housing 150.
Although a case where the protrusion section 601 provided with the arm section 160 is inserted into the opening 605 provided in the front region 157 of the housing 150, to screw and fix the arm section 160 to the housing 160 has been described as an example in the present embodiment, a terminal may be provided with the front region 157 of the housing 150 instead of the opening 605. The arm section 160 may be fixed to the housing 150 by being inserted the arm section 160 into the terminal.
The side region 158 of the housing 150 is provided with an output terminal 403. A plug of a cable (not illustrated) or the like is inserted into the output terminal 403. The cable electrically connects the signal output device 10 and the control device 50 to each other. The output terminal 403 is preferably provided at a position where the cable does not contact the drumhead 815 of the bass drum 810. The vibration signal output from the sensor 300 (300-1) is transmitted to the control device 50 via the cable connected to the output terminal 403. If a plurality of sensors 300 are provided, a vibration signal output from at least one of the sensors is transmitted to the control device 50 via the cable.
The vibration signal input unit 509 is a terminal to which an external device is connected via a cable or the like. In this example, the signal output device 10 is connected to the vibration signal input unit 509, and a vibration signal to be output from the signal output device 10 is input to the vibration signal input unit 509. The vibration signal input unit 509 outputs the input vibration signal to the beat detection unit 511.
The beat detection unit 511 detects the timing and the strength of a beat on the drumhead 815 of the bass drum 810 based on a vibration waveform represented by the vibration signal input from the vibration signal input unit 509. The timing of the beat may be a timing at which the amplitude of the vibration waveform exceeds a previously determined threshold value, for example. A peak value of the amplitude within a predetermined time period from the timing at which the amplitude exceeds the threshold value may be the strength of the beat. The beat detection unit 511 detects the strength of the beat when the timing of the beat is detected, and outputs a beat signal representing the strength to the signal processing unit 501. For example, the beat signal may be a signal in an MIDI format, and includes note-on and velocity in this case.
The signal processing unit 501 includes a sound signal generation unit 503 and an acoustic processing unit 505. The sound signal generation unit 503 generates a sound signal based on the beat signal output from the beat detection unit 511. The sound signal is generated using a sound waveform previously registered, for example, is generated by reading out a waveform obtained by recording a drumbeat of the bass drum from a memory. A plurality of types of waveforms may be registered in the memory, and a desired tone of the user may be selected by an operation of the operation unit 507.
The acoustic processing unit 505 provides an acoustic effect (e.g., reverb, delay, distortion, or compressor) corresponding to a set parameter to the sound signal input from the sound signal generation unit 503 and outputs the sound signal. The parameter may be a previously determined value, or may be a value input via the operation unit 507. The operation unit 507 is a device that receives input of an instruction by a user, e.g., a button, a knob, or a touch panel. If there are a plurality of parameters to be set, a combination of values to be respectively set for the parameters may be stored as a template, and the template to be set may be switched by operating the knob or the like. The operation unit 507 may be an external device connected to the control device 50. A pad or a foot switch used in an electronic drum or the like, for example, may be used as the external device. If the foot switch or the like is used, a tempo may be calculated from an operation interval, and a predetermined parameter (e.g., delay time) may be changed depending on the tempo. The control device 50 may calculate the tempo based on the sound signal acquired from the signal output device 10. The control device 50 may be operable by a personal computer, a smartphone, or the like.
The output unit 513 is a terminal to which an external device is connected via the cable or the like, and the external device is connected to the output unit 513 via the cable or the like. The output unit 513 outputs the sound signal output from the acoustic processing unit 505. The sound signal is fed to the external device (e.g., a headphone) connected to the output unit 513. As a result, a player of the drum set can listen to a sound generated based on a beat of the bass drum 810 using the sound radiation (external) device such as the headphone.
As described above, in the present embodiment, the extension section 161 extending from the arm section 160 of the signal output device 10 directly contacts the drumhead (portion to be struck) 815 of the bass drum 810. Accordingly, the sensor 300 can efficiently detect vibration transmitted to the arm section 160. An angle formed between an extension direction of the extension section 161 and the drumhead 815 of the bass drum 810 is a substantially right angle. Thus, sufficient vibration is transmitted to the extension section 161 from the drumhead 815, resulting in an improved detection accuracy of the sensor 300.
Further, in the present embodiment, the arm section 160 is detachable from the housing 150. Accordingly, if detection of vibration to be applied to the drumhead 815 is not required, the user can easily detach the arm section 160 from the housing 150.
In the present embodiment, attachment and detachment between the arm section 160 and the housing 150 may correspond to electrical connection and electrical disconnection between the arm section 160 and the housing 150. That is, an attachment/detachment mechanism between the arm section 160 and the housing 150 may also serve as an electrical connection section between the arm section 160 and the housing 150. Although a case where the signal output device 10 is attached to the rim 818 has been described in the present embodiment, an attachment position of the signal output device 10 is not limited to the rim 818. For example, the signal output device 10 can also be fixed to the lugs of the drum.
The signal output device according to the first embodiment described above has a configuration in which the arm section provided with the sensor is detachable from the housing. Accordingly, the user can detach the arm section from the housing, as needed. In a second embodiment, a signal output device capable of changing a position of an arm section without detaching an arm section from a housing will be described.
The arm section 701 is rotatably attached to the housing 150 by an attachment section 705. As illustrated in
In the present embodiment, a sensor 300 (300-1) is arranged in the arm section 701, like in the first embodiment. However, a position where the sensor 300 (300-1) is arranged is not limited to the arm section 701. The sensor 300 (300-1) may be arranged on an extension section 703 extending from the arm section 701. The extension section 703 contacts a drumhead 815 of a bass drum 810, which is not illustrated. At this time, an angle θ formed between an extension direction of the extension section 703 and the drumhead 815 is preferably a substantially right angle. Vibration applied to the drumhead 815 of the bass drum 810 is transmitted to the arm section 701 through the extension section 703. The sensor 300 (300-1) provided on the arm section 701 detects the vibration transmitted to the arm section 701.
In the present embodiment, the extension section 703 extending from the arm section 701 of the signal output device 10A directly contacts the drumhead 815 of the bass drum 810, like in the first embodiment. Thus, the sensor 300 (300-1) can efficiently detect vibration transmitted to the arm section 701. The angle formed between the extension direction of the extension section 703 and the drumhead 815 of the bass drum 810 is a substantially right angle. Thus, sufficient vibration is transmitted to the extension section 703 from the drumhead 815, resulting in an improved detection accuracy of the sensor 300 (300-1). Further, in the present embodiment, the arm section 701 is rotatably attached to the housing 150. Accordingly, if detection of vibration to be applied to the drumhead 815 is not required, a user may move the arm section 701 in an upward direction opposite to the extension direction of the extension section 703. Since the arm section 701 rotates relative to the housing 150 with the attachment section 705 used as an axis, the arm section 701 can be easily separated from the drumhead 815 without being detached from the housing 150.
Although an example in which the sensor 300 (300-1) is provided on the arm section 701 has been described in the present embodiment, the sensor 300 (300-1) may be arranged on the extension section 703 or the side region 158, an intermediate region 155, or a lower region 153 of the housing 150. The sensor 300 (300-1) may be arranged within the housing 150. The number of sensors is not limited to one. Two or more sensors may be provided. If a plurality of sensors are provided, the plurality of sensors may be arranged on/in the same position or may be respectively arranged on/in different positions. If two sensors are used, for example, the one sensor 300 (300-1) may be arranged on the arm section 701, and the other sensor 300 (300-2) may be arranged on the intermediate region 155 of the housing 150, as illustrated in
As illustrated in
In the present embodiment, a sensor 903 is provided within the housing 150. The sensor 903 detects the vibration transmitted to the arm section 901 from the drumhead of the bass drum. A position where the sensor 903 is arranged is not limited to the inside of the housing 150. The sensor 903 may be arranged on the arm section 901 and the distal end portion 901a of the arm section 901. A plurality of sensors 903 may be provided in the signal output device 10B. If the plurality of sensors 903 are provided, the plurality of sensors 903 may be arranged at the same position or may be respectively arranged at different positions. If two sensors are used, for example, the one sensor may be arranged on the distal end portion 901a of the arm section 901, and the other sensor may be arranged within the housing 150.
In the present embodiment, the arm section 901 in the signal output device 10B directly contacts the drumhead of the bass drum, like in the above-described first embodiment and second embodiment. Accordingly, the sensor 903 can efficiently detect vibration transmitted to the arm section 901. In the signal output device 10B, the arm section 901 has an extension/retraction mechanism. Accordingly, if detection of vibration to be applied to the drumhead is not required, a user can easily separate the arm section 901 from the drumhead 815 without detaching the arm section 901 from the housing 150 by reducing the length of the arm section 901. Since the arm section 901 has the extension/retraction mechanism, the user can optionally change a contact position between the arm section 901 and the drumhead by extending and retracting the arm section 901. Accordingly, in the signal output device 10B according to the present embodiment, a degree of freedom is improved for the contact position between the arm section 901 and the drumhead.
In the signal output device 10B according to the present embodiment, a swinging mechanism may be provided in a connection portion between the arm section 901 and the housing 150. When the swinging mechanism is provided, a degree of freedom can be further improved for the contact position between the arm section 901 and the drumhead.
Although an example in which the arm section 901 has the telescopic extension/retraction mechanism has been described above, the extension/retraction mechanism of the arm section 901 in the present embodiment is not limited to one of a telescopic type. For example, the arm section 901 may be a telescopic winding-up cable. In this case, the sensor may be arranged within the housing or at a distal end of the cable directly contacting the drumhead of the bass drum.
Although the embodiment of the present invention has been described above, the present invention can be implemented in various forms, as described below. For example, in the above-described embodiment, the signal output device has transmitted to the control device a vibration signal corresponding to vibration transmitted to the arm section from the drumhead. However, a sound signal generation unit in the control device may be provided in the signal output device, The signal output device and the control device may be an integral housing.
In the above-described embodiments, an example in which the signal output device according to the present invention is attached to the bass drum in the drum set has been described. However, the signal output device according to the present invention may be attached to other parts (e.g., a hoop of a snare drum).
A configuration having another function can also be applied to the signal output device according to the present invention, For example, a sound pickup device that includes a microphone and collects a sound of a bass drum may be applied to the above-described signal output device.
As illustrated in
The microphone cover 1001 is a cover section that covers at least a part of a microphone L 1105 and a microphone R 1107, described below. In a state where the signal output device 10C is installed on the bass drum 810, the microphone cover 1001 is arranged on the side of the upper region 151 of the housing 150. The microphone cover 1001 may be arranged in a region other than the upper region 151.
The signal output device 10C according to the present embodiment includes an arm section 160 attached to the housing 150 and provided with a sensor 300 (300-1), the sound pickup unit 1101, a sound signal output unit 1109, a vibration signal output unit 1111, and a detection unit 1113. A configuration of the arm section 160 is similar to that of the arm section 160 in the signal output device 10 according to the first embodiment, and hence overlapping description is omitted.
The sound pickup unit 1101 is provided within the housing 150. The sound pickup unit 1101 includes a circuit board 1103, the microphone for left channel L 1105, and the microphone for right channel R 1107. Each of the microphone L 1105 and the microphone R 1107 has directivity and converts an input sound into an electrical signal and outputs the electrical signal. The circuit board 1103 includes an amplification circuit that amplifies signals respectively output from the microphone L 1105 and the microphone R 1107, and outputs the amplified signals as sound signals (two-channel stereo) to the sound signal output unit 1109. In the present embodiment, the microphone L 1105 and the microphone R 1107 are each an electret condenser microphone (ECM). Accordingly, the circuit board 1103 includes a power supply circuit that is supplied with power from an external device via the sound signal output unit 1109 and supplies the power to the microphone L 1105 and the microphone R 1107. The power may be supplied by a battery or the like. The number of microphones provided in the sound pickup unit 1101 may be one or three or more.
The signal output device 10C may include a sensor 300 (300-2) provided to the housing 150 in addition to the sensor 300 (300-1) provided on the arm section 160 extending from the housing 150, like the signal output device 10 according to the first embodiment. Although a case where the sensor 300 (300-2) is provided on an intermediate region 155 of the housing 150 is illustrated in
The detection unit 1113 detects whether or not the sensor 300 (300-1) provided on the arm section 160 is electrically connected to the circuit board in the sound pickup unit 1101. The detection unit 1113 may judge whether or not the sensor 300 (300-1) is electrically connected to the circuit board in the sound pickup unit 1101 by detecting whether or not the arm section 160 is attached to the housing 150.
In the present embodiment, the circuit board 1103 includes an amplification circuit that amplifies the vibration signal output from the sensor 300 (300-1) or the sensor 300 (300-2), and outputs the amplified signal as a vibration signal to the vibration signal output unit 1111. The amplification circuit may be included in not the circuit board 1103 included in the sound pickup unit 1101 but another circuit board. In this case, the circuit board 1103 that processes a signal of the sensor 300 (300-2) may be connected to the housing 150. The circuit board 1103 outputs the vibration signal output from either one of the sensor 300 (300-1) and the sensor 300 (300-2). For example, the circuit board 1103 outputs the vibration signal output from the sensor 300 (300-1) when the detection unit 1113 detects that the sensor 300 (300-1) provided on the arm section 160 is electrically connected to the circuit board 1103 in the sound pickup unit 1101, and outputs the vibration signal output from the sensor 300 (300-2) when the sensor 300 (300-1) provided on the arm section 160 is not electrically connected to the circuit board 1103 in the sound pickup unit 1101. The amplification circuit that amplifies the vibration signal output from the sensor 300 (300-1) or the sensor 300 (300-2) may be omitted.
It has been described above that the circuit board 1103 outputs the vibration signal output from either one of the sensor 300 (300-1) and the sensor 300 (300-2). However, the circuit board 1103 may output the vibration signal output from at least one of the sensor 300 (300-1) and the sensor 300 (300-2). For example, the circuit board 1103 may output the vibration signals respectively output from both the sensor 300 (300-1) and the sensor 300 (300-2).
The sound signal output unit 1109 is a terminal connected to the housing 150, and an external device is connected thereto via a cable or the like. A sound signal output from the circuit board 1103 is fed to an external device (e.g., a control device 50A) connected to the sound signal output unit 1109. The vibration signal output unit 1111 is a terminal connected to the housing 150, and an external device is connected thereto via a cable or the like. A vibration signal output from the circuit board 1103 is fed to the external device (e.g., the control device 50A) connected to the vibration signal output unit 1111.
The control device 50A is installed on a high hat stand, like the control device 50 illustrated in
The control device 50A detects the timing of a beat on the drumhead 815 of the bass drum 810 and the strength of the beat based on a vibration waveform represented by a vibration signal acquired from the signal output device 10C, and generates a beat signal representing the timing and the strength of the detected beat, like the control device 50. The control device 50A generates a sound signal based on the beat signal. Further, the control device 50A acquires the sound signal from the signal output device 10C and subjects the acquired sound signal to acoustic processing.
The sound signal input unit 1301 is a terminal to which the external device is connected via a cable or the like. In this example, the signal output device 10C is connected to the sound signal input unit 1301, and the sound signal output by the signal output device 10C is input to the sound signal input unit 1301. The sound signal input unit 1301 outputs the input sound signal to the signal processing unit 501A.
The signal processing unit 501A includes an acoustic processing unit 1303 that performs acoustic processing for the sound signal input from the sound signal input unit 1301 in addition to a sound signal generation unit 503 that generates a sound signal based on a beat signal and an acoustic processing unit 505 that performs acoustic processing for the sound signal generated in the sound signal generation unit 503.
The acoustic processing unit 1303 provides an acoustic effect (e.g., reverb, delay, distortion, or compressor) corresponding to a set parameter to the sound signal input from the sound signal input unit 1301 and outputs the sound signal. The parameter may be a previously determined value, or may be a value input via the operation unit 507. The acoustic processing unit 1303 differs from the acoustic processing unit 505 in a sound signal to which an acoustic effect is to be provided. Accordingly, the acoustic processing unit 1303 may provide acoustic processing different from the acoustic processing performed by the acoustic processing unit 505 to the sound signal. The same acoustic effect may be provided to the sound signal generated by the sound signal generation unit 503 and the sound signal input from the sound signal input unit 1301. If the same acoustic effect is provided, a configuration in which an acoustic effect is provided, after the sound signal from the sound signal input unit 1301 and the sound signal from the sound signal generation unit 503 are synthesized, to the synthesized sound signals (a configuration in which the acoustic processing units 505 and 1303 are integrated) may be used.
The output unit 1305 is a terminal to which the external device is connected via a cable or the like, and the external device is connected thereto via the cable or the like. The output unit 1305 synthesizes the sound signal output from the acoustic processing unit 505 and the sound signal output from the acoustic processing unit 1303 and outputs the synthesized sound signals.
If the signal output device 10C according to the present embodiment is installed at a previously assumed position of the drum set (here, on an upper part of the bass drum 810), respective sounds of each of drums and a cymbal can be picked up. For the sound of the bass drum 810, vibration is detected by the sensor 300 (300-1) or the sensor 300 (300-2). In the control device 50A, a sound signal corresponding to a sound of the bass drum, for example, is generated based on the vibration detected by the sensor 300 (300-1) or the sensor 300 (300-2). The control device 50A provides an acoustic effect to the generated sound signal and the sound signal acquired from the signal output device 10C and outputs the sound signals.
When a player listens to the sound signals output from the control device 50A with a headphone, a predetermined amount of a live sound in a performance of the drum set is cut off by the headphone. On the other hand, the player can listen to a performance sound collected by the signal output device 10C and a sound of the bass drum generated according to vibration of the bass drum 810 from the headphone.
This application is a U.S. continuation application filed under 35 U.S.C. § 111(a), of International Application No. PCT/JP2018/003797, filed on Feb. 5, 2018, the disclosures of which are incorporated by reference.
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| Number | Date | Country | |
|---|---|---|---|
| 20200365128 A1 | Nov 2020 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/JP2018/003797 | Feb 2018 | US |
| Child | 16944239 | US |
