JP2007205824A - Electronic metronome - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electronic metronome not hindering performance of a musical instrument or the like, capable of acquiring natural lingering tone. <P>SOLUTION: Since only a click sound (tempo sound) is regenerated at a weak beating time, and each waveform of two kinds of sounds, namely, a chime sound (rhythmic sound) and the click sound (tempo sound), is mixed, regenerated and outputted at a strong beating time, even at the strong beating time, natural reverberation can be acquired, and unnaturalness characteristic to the electronic type metronome can be removed. Since the chime sound and the click sound are not a sound having a specific pitch, a user can be informed of a tempo by a sound not hindering the performance of a musical instrument. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an electronic metronome that generates a sound by reading a period of a pendulum by a sensor.

Metronomes are either mechanical or electronic. A mechanical metronome generates a sound with a specific tempo according to the vibration of the pendulum. In a mechanical metronome. It was necessary to manufacture and combine the parts that make up the metronome with high precision, requiring special manufacturing techniques, and there were difficulties in manufacturing and maintenance.
An electronic metronome and a contactless metronome disclosed in Patent Document 1 are available as solutions for solving the difficulty in manufacturing the mechanical metronome. The electronic metronome extracts a synchronization signal from the vibration of a vibrator such as quartz, and reproduces an electronic sound having a waveform stored in the waveform memory in accordance with the synchronization signal. In addition, the non-contact type metronome described in Patent Document 1 eliminates the deterioration of the accuracy of components due to wear and the like in the mechanical metronome and the difficulty in manufacturing by installing a non-contact type sensor on the pendulum. Yes.
Japanese Patent Publication No. 8-1472

However, the sound reproduced by the electronic metronome described above is a monotonous pulse sound, and there is a disadvantage that it does not have a reverberation of a chime sound and sounds unnatural. In addition, there is a disadvantage that the sound has a specific pitch (pitch), which hinders performance of an instrument or the like. Further, this disadvantage cannot be eliminated even in the contactless metronome described in Patent Document 1.
An object of the present invention is to provide an electronic metronome that eliminates the above-mentioned disadvantages, can obtain a natural reverberation, and does not hinder the performance of a musical instrument or the like.

  In order to achieve the above-described object, the metronome of the present invention includes a pendulum unit that reciprocates at a predetermined tempo, a synchronization signal that senses the reciprocation of the pendulum unit and is synchronized with the reciprocation period of the pendulum unit. Sensor, a plurality of waveform memories for storing a plurality of different time signature sounds and a plurality of different tempo sounds, and a time signature sound and a tempo sound among a plurality of time signature sounds and a plurality of tempo sounds are selected. A timbre switching unit that determines and switches between, a mixing unit that outputs a waveform signal of a mixed sound by mixing a waveform signal of a time signature sound and a waveform signal of a tempo sound stored in the plurality of waveform memories, and a sensor An output unit that reproduces a waveform signal in synchronization with the output synchronization signal and outputs it as sound, and a control unit.

  Preferably, the control unit reads the tempo sound determined by the timbre switching unit from the corresponding waveform memory when reproducing a weak beat and causes the output unit to reproduce and output the tempo sound, and when reproducing a strong beat, the control unit switches the timbre switching unit. Is read from the corresponding waveform memory, mixed by the mixing unit, and then reproduced / output by the output unit.

  Preferably, the pendulum part further has a speed control weight, and the speed control weight can be moved up and down on the pendulum part to be fixed, and a reciprocating motion tempo of the pendulum part is determined depending on a fixing position. adjust.

  Preferably, the waveform memory can record and record a new time signature and tempo sound by overwriting.

  According to the present invention, it is possible to provide an electronic metronome that can obtain a natural reverberation and does not interfere with the performance of a musical instrument or the like.

Hereinafter, embodiments of the present invention will be described.
FIG. 1 is a block diagram of an electronic metronome 100 according to this embodiment.
As shown in FIG. 1, the electronic metronome 100 includes a photosensor 1, a pendulum unit 2, a time signature switching unit 3, a timbre switching unit 4, a control unit 5, waveform memories 61 to 64, a mixing unit 7, and an output unit 8. .

As shown in FIG. 2, the photosensor 1 detects that the reflection plate 22 included in the pendulum unit 2 reciprocates and passes through each of the reflectors 22, thereby detecting the reflected light, and thereby synchronizes with the reciprocation of the pendulum unit 2. In order to obtain the sensor output, a photosensor right 1R and a photosensor left 1L are provided.
As shown in FIG. 2, the pendulum unit 2 has a speed control weight 21 and a reflecting plate 22, and reciprocates left and right around the Z point shown in FIG. The power of the reciprocating motion can be, for example, repulsion by a permanent magnet attached to the pendulum unit 2, rotation of a motor by a battery, or the like, but is not limited in this embodiment. Further, by raising and lowering the governing weight 21 on the pendulum unit 2, the tempo of the sound reproduced and output by the output unit 8 described later can be changed.

The time signature switching unit 3 selects and determines the time signature of the sound to be reproduced. In this embodiment, the time signatures that can be selected by the time signature switching unit 3 are assumed to be, for example, six types: 0 time, 2 time, 3 time, 4 time, 5 time, and 6 time.
Zero time is a setting for reproducing only the tempo sound.
The 2-time signature is a setting for reproducing one time signature sound every time two tempo sounds are reproduced.
Triple beat is a setting for playing one time signature every three tempo sounds.
The 4-time signature is a setting for reproducing one time signature sound every time four tempo sounds are reproduced.
The five time signature is a setting for reproducing one time signature sound every time the tempo sound is reproduced five times.
The 6 time signature is a setting for reproducing one time signature sound every 6 tempo sound reproductions.
In this embodiment, it is assumed that the click sound is used as the tempo sound and the chime sound is used as the time signature.
As an example, FIG. 3 shows a timing chart of a chime sound and a click sound in the case of 3 beats.
That is, as shown in FIG. 3, in the case of 3 beats, the next chime sound is reproduced simultaneously with the third click sound after the chime sound (beat sound) is reproduced. That is, in the case of N time signature, the next chime sound is reproduced at the same time as the Nth click sound after the chime sound is reproduced (N is 2, 3, 4, 5 or 6).

  The time signature switching unit 3 counts time signatures. The counting method will be described later in an operation example.

The tone color switching unit 4 selects and determines the tone color of the sound to be reproduced. In this embodiment, for example, it is assumed that two types of timbres, timbre A and timbre B, can be selected.
The control unit 5 performs overall control of the electronic metronome 100.
Each of the waveform memories 61 to 64 stores a waveform of one sound. In the present embodiment, it is assumed that there are two types of sounds (chimes and clicks) for each tone, and two types of tones, tone A and tone B, are stored. That is, it is assumed that the waveform memory 61 stores the chime sound A, the waveform memory 62 stores the click sound A, the waveform memory 63 stores the chime sound B, and the waveform memory 64 stores the click sound B.

The mixing unit 7 mixes the chime sound of the timbre A or the timbre B and the click sound under the control of the control unit 5. That is, the waveform of each sound is read from the waveform memories 61 to 64, and the waveforms of the chime sound A and the click sound A or the chime sound B and the click sound B are read and mixed according to the control of the control unit 5.
The output unit 8 reproduces the waveform read from the waveform memory as a sound.

Next, an operation example of the electronic metronome 100 of this embodiment will be described.
4 and 5 are flowcharts for explaining an operation example of the electronic metronome 100.

Step ST1:
The time signature switching unit 3 reads the time signature setting and outputs it to the control unit 5. The time signature switching unit 3 sets a time signature counter. That is, when the X time signature is set, the time signature switching unit sets the time signature counter to “X”.
Step ST2:
When the pendulum unit 2 starts reciprocating movement and the reflector 22 crosses the photo sensor 1 and the sensor senses an input, the process proceeds to step ST3, and when the input is not sensed, the step ST2 is repeated.

Step ST3:
If the sensor that sensed the input in step ST2 is the photosensor right 1R, the process proceeds to step ST4, and if it is the photosensor left 1L, the process proceeds to step ST5.
Step ST4:
The photosensor right 1R sets the left and right flags indicating the direction in which the pendulum unit 2 has swung to “0”. The left / right flag “0” means that the pendulum unit 2 has swung to the right.

Step ST5:
The left 1L of the photo sensor sets the left / right flag indicating the direction in which the pendulum unit 2 has swung to “1”. The left / right flag “1” means that the pendulum unit 2 has swung to the left.
Step ST6:
When the time signature setting of the time signature switching unit 3 is other than 0 time, the process proceeds to step ST7, and when it is 0 time, the process proceeds to step ST15.

Step ST7:
The time signature switching unit 3 decrements by 1 from the current time signature counter. As a result, the sound for one beat is reproduced.
Step ST8:
When the timbre setting of the timbre switching unit 4 is timbre A, the process proceeds to step ST9, and when it is timbre B, the process proceeds to step ST12.

Step ST9:
The control unit 5 reads the waveform of the chime sound A from the waveform memory 61 and reads the waveform of the click sound A from the waveform memory 62.
Step ST10:
The mixing unit 7 mixes the waveform of the chime sound A read in step ST9 and the waveform of the click sound A.

Step ST11:
The output unit 8 reproduces and outputs the waveform mixed by the mixing unit 7 in step ST10 as sound.
Step ST12:
The control unit 5 reads the waveform of the chime sound B from the waveform memory 63 and reads the waveform of the click sound B from the waveform memory 64.

Step ST13:
The mixing unit 7 mixes the waveform of the chime sound B read in step ST12 and the waveform of the click sound B.
Step ST14:
The output unit 8 reproduces and outputs the waveform mixed by the mixing unit 7 in step ST13 as sound.

Step ST15:
When the timbre setting of the timbre switching unit 4 is timbre A, the process proceeds to step ST16, and when it is timbre B, the process proceeds to step ST18.
Step ST16:
The control unit 5 reads the waveform of the click sound A from the waveform memory 62.

Step ST17:
The output unit 8 reproduces and outputs the click sound A read by the control unit 5 in step ST16.
Step ST18:
The control unit 5 reads the waveform of the click sound B from the waveform memory 64.

Step ST19:
The output unit 8 reproduces and outputs the click sound B read by the control unit 5 in step ST18.
Step ST20:
If the time signature setting unit 3 switches the time signature setting, the process returns to step ST1, and if not, the process proceeds to step ST21.

Step ST21:
The control unit 5 proceeds to step ST22 when the left / right flag is “1”, that is, when the pendulum unit 2 has just swung to the left, and proceeds to step ST24 when the left / right flag is “0”. move on.
Step ST22:
The photosensor right 1R proceeds to step ST23 when there is an input, and returns to step ST20 when there is no input.

Step ST23:
The photosensor right 1R sets the left and right flags indicating the direction in which the pendulum unit 2 has swung to “0”. The left / right flag “0” means that the pendulum unit 2 has swung to the right.

Step ST24:
The photosensor left 1L proceeds to step ST25 when there is an input, and returns to step ST20 when there is no input.
Step ST25:
The left 1L of the photo sensor sets the left / right flag indicating the direction in which the pendulum unit 2 has swung to “1”. The left / right flag “1” means that the pendulum unit 2 has swung to the left.

Step ST26:
When the time signature of the time signature switching unit 3 is other than 0 time, the process proceeds to step ST27, and when it is 0 time, the process proceeds to step ST37.
Step ST27:
The time signature switching unit 3 decrements by 1 from the current time signature counter.

Step ST28:
The time signature switching unit 3 determines whether or not the time signature counter is 0. If it is 0, the process proceeds to step ST29. If it is not 0, the process proceeds to step ST37.
Step ST29:
The time signature switching unit 3 newly sets a counter. That is, the counter is returned to “X”.

Step ST30:
When the timbre setting of the timbre switching unit 4 is timbre A, the process proceeds to step ST31, and when it is timbre B, the process proceeds to step ST34.
Step ST31:
The control unit 5 reads the waveform of the chime sound A from the waveform memory 61 and reads the waveform of the click sound A from the waveform memory 62.

Step ST32:
The mixing unit 7 mixes the waveform of the chime sound A read in step ST31 with the waveform of the click sound A.
Step ST33:
The output unit 8 reproduces and outputs the waveform mixed by the mixing unit 7 in step ST32 as sound.

Step ST34:
The control unit 5 reads the waveform of the chime sound B from the waveform memory 63 and reads the waveform of the click sound B from the waveform memory 64.
Step ST35:
The mixing unit 7 mixes the waveform of the chime sound B read in step ST34 and the waveform of the click sound B.

Step ST36:
The output unit 8 reproduces and outputs the waveform mixed by the mixing unit 7 in step ST35 as sound.
Step ST37:
If the tone color setting of the tone color switching unit 4 is tone color A, the process proceeds to step ST38, and if it is tone color B, the process proceeds to step ST40.

Step ST38:
The control unit 5 reads the waveform of the click sound A from the waveform memory 62.
Step ST39:
The output unit 8 reproduces and outputs the click sound A read by the control unit 5 in step ST38.

Step ST40:
The control unit 5 reads the waveform of the click sound B from the waveform memory 64.
Step ST41:
The output unit 8 reproduces and outputs the click sound B read by the control unit 5 in step ST40.

  As described above, according to the electronic metronome 100 of the present embodiment, only a click sound (tempo sound) is reproduced during a weak beat, and a chime sound (beat sound) and a click sound (tempo sound) are generated during a strong beat. Since various types of sound waveforms are mixed and played back / output, natural reverberation can be obtained even during strong beats, and the unnaturalness inherent to electronic metronome can be eliminated. Further, since the chime sound and the click sound are not sounds having a specific pitch, the tempo can be notified to the user by a sound that does not interfere with the performance of the musical instrument.

The present invention is not limited to the embodiment described above.
That is, those skilled in the art may make various modifications, combinations, subcombinations, and alternatives regarding the components of the above-described embodiments within the technical scope of the present invention or an equivalent scope thereof.

Although the electronic metronome 100 of this embodiment has two kinds of timbres and has a chime sound and a click sound for each timbre, the present invention is not limited to this. That is, for example, a waveform of a chime sound is stored in the waveform memory 61, a waveform of a click sound is stored in advance in the waveform memory 62, and the waveform memories 63 and 64 can store a waveform of a desired tone color. Good. In this case, if a user's favorite tone color is recorded from a microphone or the like (not shown), the user's favorite tone color can be reproduced and output instead of the chime sound and click sound of the above embodiment. As a result, a user who wants to use sounds other than the chime sound and click sound can be notified of the tempo with a favorite tone color.
The left / right detection method (left / right flag) and the time signature counting method (time signature counter) in the operation example described in FIGS. 4 and 5 of the present embodiment are examples, and the present invention is not limited to this.

FIG. 1 is a block diagram of an electronic metronome 100 according to this embodiment. FIG. 2 is a diagram illustrating a configuration example of the photosensor 1 and the pendulum unit 2. FIG. 3 is a diagram showing a timing chart of time signature sounds and tempo sounds in the case of three time signatures. FIG. 4 is a flowchart for explaining an operation example of the electronic metronome 100. FIG. 5 is a flowchart for explaining an operation example of the electronic metronome 100.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 100 ... Electronic metronome, 1 ... Photo sensor, 2 ... Pendulum part, 21 ... Adjusting weight, 22 ... Reflecting plate, 3 ... Time signature switching part, 4 ... Tone switching part, 5 ... Control part, 61, 62, 63, 64 ... Waveform memory, 7 ... Mixing unit, 8 ... Output unit

Claims (4)

A pendulum that reciprocates at a predetermined tempo;
A sensor that senses the reciprocating motion of the pendulum part and outputs a synchronization signal synchronized with the reciprocating period of the pendulum part;
A plurality of waveform memories for storing different time signatures and different tempo sounds;
A timbre switching unit that determines and switches which time signature and tempo sound is selected from among a plurality of time signature sounds and a plurality of tempo sounds;
A mixing unit that outputs a waveform signal of a mixed sound by mixing a waveform signal of a time signature sound and a waveform signal of a tempo sound stored in the plurality of waveform memories;
An output unit that reproduces a waveform signal in synchronization with the synchronization signal output by the sensor, and outputs the signal as a sound;
A control unit;
An electronic metronome. The control unit reads the tempo sound determined by the timbre switching unit from the corresponding waveform memory at the time of reproducing a weak beat, and causes the output unit to reproduce and output the tempo sound, and the time signature determined by the timbre switching unit at the time of playing a strong beat The electronic metronome according to claim 1, wherein a sound and a tempo sound are read from the corresponding waveform memory, mixed by the mixing unit, and then reproduced and output by an output unit. The pendulum part further has a speed control weight,
3. The electronic metronome according to claim 1, wherein the speed control weight can be fixed by moving up and down on the pendulum part, and adjusting a tempo of reciprocation of the pendulum part according to a fixing position. The electronic metronome according to any one of claims 1 to 3, wherein the waveform memory is capable of recording and overwriting a new time signature and tempo sound.

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