JP2007232513A - Electronic metronome - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electronic metronome of which the pendulum does not move spontaneously even when the pendulum is unlocked. <P>SOLUTION: A control section 7 outputs a control signal PO1 to a pendulum drive section 3. When the control signal PO1 is at a high level, power is not supplied to a drive circuit 32 of the pendulum drive section 3. When the control signal PO1 is at a low level, power is supplied to the drive circuit 32 of the pendulum drive section 3, thereby allowing the drive circuit 32 to drive the pendulum 2. <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 the mechanical metronome, it is necessary to manufacture and combine the parts that make up the metronome with high precision, and special manufacturing techniques are required, which causes difficulties in manufacturing and maintenance.
An electronic metronome is used to eliminate the difficulty in manufacturing this 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.

  However, in general, the sound reproduced by the electronic metronome is a monotonous pulse sound, has no reverberation of a chime sound, and sounds unnatural. Moreover, it is a sound having a specific pitch (pitch), which is an obstacle when playing a musical instrument or the like.

As a means for eliminating the disadvantages of the mechanical metronome and the electronic metronome described above, for example, in Patent Document 1, a pendulum is driven by a drive circuit, and a sound having no specific pitch is reproduced in accordance with the period of the pendulum. An electronic metronome is disclosed.
Japanese Patent Laid-Open No. 06-214057

However, in an electronic metronome that reproduces sound according to the period of the pendulum as described above, for example, when the power is turned on without locking the pendulum, an impact current flows through the drive circuit that drives the pendulum, There was a disadvantage that the pendulum might move freely.
Also, in connection with this, in the case of a pendulum with good startability, the pendulum will start to swing due to slight vibrations, such as moving the electronic metronome or shaking the table on which the electronic metronome is placed, There was a disadvantage.

  An object of the present invention is to provide an electronic metronome that eliminates the disadvantages described above and prevents the pendulum from moving freely even when the pendulum is unlocked.

  In order to achieve the above-described object, an electronic metronome according to the present invention includes a pendulum, a pendulum driving unit that reciprocates the pendulum at a predetermined tempo, senses that the pendulum has passed, and reciprocates the pendulum. A sensor that outputs a synchronization signal synchronized with the cycle, a plurality of waveform memories that store at least one time signature sound, and at least one tempo sound, and a time signature sound and a tempo sound stored in the plurality of waveform memories A tone color switching unit that determines and switches the sound to be reproduced, a mixing unit that mixes the waveform signal of the time signature sound and the waveform signal of the tempo sound, and outputs a waveform signal of the mixed sound, and the synchronization output from the sensor An output unit that reproduces and outputs a waveform signal output from the mixing unit in synchronization with a signal, a control unit, and a power switch; A control signal is output to the pendulum drive unit. Immediately after the power is turned on by the power switch, the pendulum drive unit takes the drive in a stopped state immediately after the power is turned on, and the sensor senses the passage of the pendulum for the first time after the power is turned on. On this condition, the pendulum driving unit is controlled so as to cause the pendulum to reciprocate.

  Preferably, when the pendulum is reciprocating, the control unit holds the pendulum in a stopped state when the sensor does not detect passage of the pendulum for longer than the tempo period. The control signal is output as follows.

  According to the present invention, it is possible to provide an electronic metronome in which the pendulum does not start moving even when the pendulum is unlocked.

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 2, a pendulum drive unit 3, a time signature switching unit 4, a tone color switching unit 5, a power switch unit 6, a control unit 7, waveform memories 81 to 84, A mixing unit 9, a D / A conversion circuit 10, and an output unit 11 are included.

As shown in FIG. 2, the photosensor 1 (sensor) detects that light is reflected by reciprocating a reflecting plate 22 included in a pendulum 2 described later and crossing each of the reflectors 22, thereby reciprocating the pendulum 2. In order to obtain a sensor output synchronized with the movement, a photosensor right 1R and a photosensor left 1L are provided.
As shown in FIG. 2, the pendulum 2 has a speed control weight 21, a reflecting plate 22, and a magnet 23, and reciprocates left and right with the Z point shown in FIG. 2 as a fulcrum.
The governing weight 21 can move up and down on the pendulum 2, and by moving up and down, the period of the reciprocating motion of the pendulum 2 changes, and the output unit 11 described later changes the tempo of the sound that is reproduced and output. Can do.
The reflection plate 22 is a plate that reflects light, and is fixed to the lower portion of the pendulum 2.
The magnet 23 crosses in front of a detection coil 321 of a drive circuit 32 to be described later by the pendulum movement of the pendulum 2, and drives the pendulum 2 by the drive circuit.

The pendulum drive unit 3 performs drive control of the pendulum 2 based on a control signal PO1 from the control unit 7 described later.
In the present embodiment, the pendulum driving unit 3 stops the pendulum 2 when the control signal PO1 is at a high level, and drives the pendulum 2 when the control signal PO1 is at a low level.
The configuration of the pendulum driving unit 3 will be described in detail later.

The time signature switching unit 4 selects and determines the time signature of the sound to be reproduced. In this embodiment, it is assumed that there are six types of time signatures that can be selected by the time signature switching unit 4, for example, 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.
The time signature switching unit 4 counts time signatures. The counting method will be described later in an operation example.

The tone color switching unit 5 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 power switch unit 6 is a switch unit for turning on / off the power source of the electronic metronome 100.

The control unit 7 performs overall control of the electronic metronome 100.
Further, the control unit 7 outputs a control signal PO <b> 1 to the pendulum driving unit 3. The control signal PO1 is a digital signal of either high level or low level.
In addition, the control unit 7 further includes a clock timer 71. The clock timer 71 measures the time after the photosensor 1 senses an input.

The waveform memories 81 to 84 each store one sound waveform. In the present embodiment, there will be described a case where there are two types of sounds (chimes and clicks) per tone color, and tone color A and tone color B are stored. That is, the waveform memory 81 stores a chime sound A, the waveform memory 82 stores a click sound A, the waveform memory 83 stores a chime sound B, and the waveform memory 84 stores a click sound B.
In this embodiment, it is assumed that a chime sound is used as the time signature and the click sound is used as the tempo sound.

The mixing unit 9 mixes and outputs the waveform signals of the timbre A or the timbre B chime sound and the click sound under the control of the control unit 7. That is, the waveform of each sound is read from the waveform memories 81 to 84, 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 7. Alternatively, when only the tempo sound is reproduced, the waveform signal of the click sound A or B is read from the waveform memory 82 or 84 and output to the D / A conversion circuit described later.
The D / A conversion circuit 10 converts the digital waveform signal output from the mixing unit 9 into an analog signal.
The output unit 11 reproduces and outputs the analog signal converted and output by the D / A conversion circuit.

Next, a configuration example of the pendulum driving unit 3 in the electronic metronome 100 of the present embodiment will be described.
FIG. 3 is a diagram illustrating an example of a circuit diagram of the pendulum driving unit 3.
As shown in FIG. 3, the pendulum drive unit 3 includes a power supply VDD, a constant voltage IC 31, a drive circuit 32, capacitors C1 to C4, and resistors R1 and R2.

  The constant voltage IC 31 is a four-terminal regulator in this embodiment, and has four terminals for IN, OUT, GND, and set voltage control. The IN terminal is connected to the power supply VDD, the OUT terminal is connected to the drive circuit 32, and a terminal (control terminal) for setting voltage control is connected to the control unit 7. Capacitors C1 and C2 are connected to the IN terminal and OUT terminal to prevent oscillation.

As shown in FIG. 3, the drive circuit 32 includes a detection coil 321, a drive coil 322, capacitors C3 and C4, resistors R1 and R2, and a transistor TR1.
The capacitors C3 and C4 are charged and discharged by the current induced in the detection coil 321 as the magnet 23 passes, the transistor TR1 is opened and closed, and the drive voltage applied to the drive coil 322 is controlled. The magnet 23 is attracted by the electromagnetic force generated in the drive coil 322 by the drive voltage, and the pendulum 2 reciprocates (oscillates).

  In the pendulum drive unit 3, the output voltage from the OUT terminal of the constant voltage IC 31 changes when the control signal PO <b> 1 generated by the control unit 7 is input from the control terminal. Specifically, for example, when the control signal PO1 is at a low level, a constant voltage + V is output from the OUT terminal, and when the control signal PO1 is at a high level, the function of the constant voltage IC31 is shut down and the output from the OUT terminal is ground potential ( 0V). Thus, when the control signal PO1 is at a low level, power is supplied to the drive circuit 32 and the drive circuit 32 performs the above-described operation. However, when the control signal PO1 is at a high level, power is not supplied to the drive circuit 32. The drive circuit 32 does not operate.

Hereinafter, an operation example of the electronic metronome 100 of the present embodiment will be described.
4, 5, and 6 are flowcharts for explaining an operation example of the electronic metronome 100.

Step ST1:
When the power source of the electronic metronome 100 is turned on, the control unit 7 sets the control signal PO1 to a high level and outputs the control signal PO1 to the pendulum driving unit 3 (that is, control is performed so that power is not supplied to the driving circuit 32). The output of the D / A conversion circuit 10 is set to 0V (initial setting). In addition, the clock timer 71 is started.
Step ST2:
The time signature switching unit 4 reads the time signature setting and outputs it to the control unit 7. The time signature switching unit 4 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 ST3:
When the pendulum 2 is swung by the user, the reflecting plate 22 crosses the photosensor 1. If the sensor detects an input, the process proceeds to step ST4. If the input is not detected, the process proceeds to step ST6.
Step ST4:
When there is an input to the sensor in step ST3, the control unit 7 resets the time measuring timer 71.

Step ST5:
The control unit 7 sets the control signal PO1 to a low level, and gently changes the output of the D / A conversion circuit 10 up to the offset voltage VDD / 2.
Here, when the control signal PO1 is set to a low level, power is supplied to the drive circuit 32, and as described above, a current flows through the drive coil in response to the swinging of the pendulum 2, and the pendulum 2 performs a reciprocating motion. start.
Step ST6:
When there is no input to the sensor in step ST3, the control unit 7 causes the time measuring timer 71 to continue counting.

Step ST7:
The controller 7 returns to step ST1 when the count of the timer 71 becomes equal to or greater than the specified time, that is, the maximum value of the tempo cycle, and returns to step ST3 when it does not exceed the maximum value of the tempo cycle. For example, when the tempo is 60 (setting that the tempo sound sounds 60 times per minute), the maximum value of the tempo period is 1 second.
Step ST8:
If the sensor that sensed the input in step ST2 is the photosensor right 1R, the process proceeds to step ST9, and if it is the photosensor left 1L, the process proceeds to step ST10.

Step ST9:
The photosensor right 1R sets the left and right flags indicating the direction in which the pendulum 2 is swung to “0”. The left / right flag “0” means that the pendulum 2 has swung to the right.
Step ST10:
The left 1L of the photo sensor sets a left / right flag indicating the direction in which the pendulum 2 is swung to “1”. The left / right flag “1” means that the pendulum 2 has swung to the left.
Step ST11:
When the time signature of the time signature switching unit 4 is other than 0 time, the process proceeds to step ST12, and when it is 0 time, the process proceeds to step ST20.

Step ST12:
The time signature switching unit 4 decrements by 1 from the current time signature counter. This operation is an operation of counting that the sound for one beat is reproduced.
Step ST13:
When the timbre setting of the timbre switching unit 5 is timbre A, the process proceeds to step ST14, and when it is timbre B, the process proceeds to step ST17.

Step ST14:
The control unit 7 reads the waveform of the chime sound A from the waveform memory 81 and reads the waveform of the click sound A from the waveform memory 82.
Step ST15:
The mixing unit 9 mixes the waveform of the chime sound A read in step ST14 with the waveform of the click sound A.

Step ST16:
The output unit 11 reproduces and outputs the waveform mixed by the mixing unit 9 in step ST15 as sound.
Step ST17:
The control unit 7 reads the waveform of the chime sound B from the waveform memory 83 and reads the waveform of the click sound B from the waveform memory 84.

Step ST18:
The mixing unit 9 mixes the waveform of the chime sound B read in step ST17 and the waveform of the click sound B.
Step ST19:
The output unit 11 reproduces and outputs the waveform mixed by the mixing unit 9 in step ST18 as sound.

Step ST20:
When the timbre setting of the timbre switching unit 5 is timbre A, the process proceeds to step ST21, and when it is timbre B, the process proceeds to step ST23.
Step ST21:
The control unit 7 reads the waveform of the click sound A from the waveform memory 82.

Step ST22:
The output unit 11 reproduces and outputs the click sound A read by the control unit 7 in step ST21.
Step ST23:
The control unit 7 reads the waveform of the click sound B from the waveform memory 84.

Step ST24:
The output unit 11 reproduces and outputs the click sound B read by the control unit 7 in step ST23.
Step ST30:
If the time signature setting unit 4 switches the time signature setting, the process returns to step ST2, and if not, the process proceeds to step ST31.

Step ST31:
The control unit 7 proceeds to step ST32 when the current left / right flag is “1”, that is, when the pendulum 2 has just swung to the left, and when the current left / right flag is “0”. Proceed to step ST35.
Step ST32:
The photosensor right 1R proceeds to step ST33 when there is an input, and proceeds to step ST60 when there is no input.

Step ST33:
The control unit 7 resets the clock timer 71.
Step ST34:
The photosensor right 1R sets the left and right flags indicating the direction in which the pendulum 2 is swung to “0”. The left / right flag “0” means that the pendulum 2 has swung to the right.

Step ST35:
The photosensor left 1L proceeds to step ST36 if there is an input, and proceeds to step ST60 if there is no input.
Step ST36:
The control unit 7 resets the clock timer 71.

Step ST37:
The left 1L of the photo sensor sets a left / right flag indicating the direction in which the pendulum 2 is swung to “1”. The left / right flag “1” means that the pendulum 2 has swung to the left.
Step ST38:
When the time signature setting of the time signature switching unit 4 is other than 0 time, the process proceeds to step ST39, and when it is 0 time, the process proceeds to step ST49.
Step ST39:
The time signature switching unit 4 decrements by 1 from the current time signature counter.

Step ST40:
The time signature switching unit 4 determines whether or not the time signature counter is 0. If it is 0, the process proceeds to step ST41. If it is not 0, the process proceeds to step ST49.
Step ST41:
The time signature switching unit 4 newly sets a counter. That is, the counter is returned to “X”.

Step ST42:
When the timbre setting of the timbre switching unit 5 is timbre A, the process proceeds to step ST43, and when it is timbre B, the process proceeds to step ST46.
Step ST43:
The control unit 7 reads the waveform of the chime sound A from the waveform memory 81 and reads the waveform of the click sound A from the waveform memory 82.

Step ST44:
The mixing unit 9 mixes the waveform of the chime sound A read in step ST43 and the waveform of the click sound A.
Step ST45:
The output unit 11 reproduces and outputs the waveform mixed by the mixing unit 9 in step ST44 as sound.

Step ST46:
The control unit 7 reads the waveform of the chime sound B from the waveform memory 83 and reads the waveform of the click sound B from the waveform memory 84.
Step ST47:
The mixing unit 9 mixes the waveform of the chime sound B read in step ST46 and the waveform of the click sound B.

Step ST48:
The output unit 11 reproduces and outputs the waveform mixed by the mixing unit 9 in step ST47 as sound.
Step ST49:
When the timbre setting of the timbre switching unit 5 is timbre A, the process proceeds to step ST50, and when it is timbre B, the process proceeds to step ST52.

Step ST50:
The control unit 7 reads the waveform of the click sound A from the waveform memory 82.
Step ST51:
The output unit 11 reproduces and outputs the click sound A read by the control unit 7 in step ST50.

Step ST52:
The control unit 7 reads the waveform of the click sound B from the waveform memory 84.
Step ST53:
The output unit 11 reproduces and outputs the click sound B read by the control unit 7 in step ST52.

Step ST60:
The control unit 7 causes the clock timer 71 to count.
Step ST61:
The control unit 7 returns to step ST1 when the count of the time measuring timer 71 becomes equal to or greater than the maximum value of the specified time, that is, the tempo cycle, and returns to step ST30 when it does not exceed the maximum value of the tempo cycle.

  FIG. 7 shows a timing chart when the setting of the time signature switching unit 4 is set to three time signatures as an example of a timing chart of the electronic metronome of the present embodiment.

  As described above, according to the electronic metronome 100 of this embodiment, after the power is turned on, the control unit 7 controls the high level until the pendulum 2 is swung by the user and the photosensor 1 senses an input. Since the signal PO1 is continuously output to the pendulum drive unit 3, no power is supplied to the drive circuit 32 of the pendulum drive unit 3 and no drive current flows, so that the pendulum 2 can be prevented from starting unintentionally.

  Further, according to the electronic metronome 100 of this embodiment, unless the pendulum 2 is swung by the user to a position where the photosensor 1 can sense, no power is supplied to the drive circuit 32 of the pendulum drive unit 3 and the pendulum 2 starts to move. Since there is not, the situation where the pendulum 2 starts moving with a slight vibration can be prevented.

  Further, according to the electronic metronome 100 of the present embodiment, the control unit 7 causes the clock timer 71 to count the time, and when there is no sensor input for a time equal to or greater than the maximum value of the tempo cycle, the control signal PO1 issued by the control unit 7 Since the operation of the drive circuit 32 of the pendulum drive unit 3 is stopped at a high level, the operation is stabilized.

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 81, a waveform of a click sound is stored in advance in the waveform memory 82, and the waveform memories 83 and 84 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, the user who wants to use sounds other than the chime sound and click sound can be notified of the tempo with the user's 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, 5, and 6 of the present embodiment are examples, and the present invention is not limited to this.

In the present embodiment, the configuration of the pendulum drive unit 3 is shown in FIG. 3, but this is only an example, and for example, a configuration as shown in FIG. 8 or FIG. 9 may be used.
Each configuration will be briefly described below.

FIG. 8 is a diagram illustrating an example of a configuration of the pendulum driving unit 3 different from that of the present embodiment.
As shown in FIG. 8, the pendulum drive unit 3 includes a constant voltage IC 31, a drive circuit 32, capacitors C1 and C2, a resistor R3, and a transistor TR2.
Since the constant voltage IC 31 and the drive circuit 32 (and each configuration of the drive circuit 32) are the same as those described in the present embodiment, the description thereof is omitted.
The control signal PO1 output from the control unit 7 is input to the base of the transistor TR2. That is, when the control signal PO1 is at a high level, the transistor TR2 is turned off and the voltage from the power supply VDD is not supplied to the constant voltage IC and the drive circuit 32. Conversely, when the control signal PO1 is at a low level, the transistor TR2 is turned on, the voltage of the power supply VDD is supplied to the constant voltage IC 31 and the drive circuit 32, and the drive circuit 32 operates.

FIG. 9 is a diagram illustrating another example of the configuration of the pendulum driving unit 3 different from that of the present embodiment.
As shown in FIG. 9, the pendulum drive unit 3 includes a drive circuit 32, a resistor R4, and a transistor TR3.
Since the drive circuit 32 (and each configuration of the drive circuit 32) is the same as the example described in the present embodiment, the description thereof is omitted.
The control signal PO1 output from the control unit 7 is input to the base of the transistor TR3. When the control signal PO1 is at a high level, the transistor TR3 is turned on, so that no current flows through the transistor TR1 of the driving circuit 32 and the transistor TR3 is turned off. Thus, no drive voltage is generated in the drive coil 322. Conversely, when the control signal PO1 is at a low level, the transistor TR3 is turned off, so that a current flows through the transistor TR1 and is turned on, a drive voltage is applied to the drive coil 322, and the pendulum 2 is driven.

  That is, the pendulum driving unit 3 shown in the above-described embodiment (FIG. 3) and FIGS. 8 and 9 stops its operation when the control signal PO1 from the control unit 7 is at a high level, and the control signal PO1 is at a low level. Sometimes they are common in that they operate. That is, the pendulum drive unit 3 of the present invention can be operated as long as the operation is stopped when the control signal PO1 from the control unit 7 is at a high level and the operation is performed when the control signal PO1 is at a low level. But you can. Furthermore, the high level and low level of the control signal PO1 may be reversed. That is, it may be configured such that the operation is performed when the control signal PO1 is at a high level, and the operation is stopped when the control signal PO1 is at a low level.

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 2. FIG. 3 is a diagram illustrating a configuration example of the pendulum driving unit 3. 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. FIG. 6 is a flowchart for explaining an operation example of the electronic metronome 100. FIG. 7 is a diagram illustrating a timing chart of each signal in the case of three beats. FIG. 8 is a diagram illustrating an example of a configuration of the pendulum driving unit 3 different from that of the present embodiment. FIG. 9 is a diagram illustrating another example of the configuration of the pendulum driving unit 3 different from that of the present embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Photo sensor, 1L ... Photo sensor left, 1R ... Photo sensor right, 2 ... Pendulum, 21 ... Speed control weight, 22 ... Reflector plate, 23 ... Magnet, 3 ... Pendulum drive part, 31 ... Constant voltage IC, 32 ... Drive circuit, 321 ... detection coil, 322 ... drive coil, 4 ... time signature switching unit, 5 ... tone color switching unit, 6 ... power switch unit, 7 ... control unit, 71 ... time timer, 81, 82, 83, 84 ... waveform Memory, 9 ... mixing unit, 10 ... D / A conversion circuit, 11 ... output unit, 100 ... electronic metronome, TR1, TR2, TR3 ... transistor

Claims (2)

With a pendulum,
A pendulum drive unit that reciprocates the pendulum at a predetermined tempo;
A sensor that senses that the pendulum has passed and outputs a synchronization signal synchronized with a reciprocating period of the pendulum;
A plurality of waveform memories for storing at least one time signature and at least one tempo;
A timbre switching unit that determines and switches the sound to be reproduced from among the time signature and tempo sounds stored in the plurality of waveform memories;
A mixing unit that mixes the waveform signal of the beat sound and the waveform signal of the tempo sound to output a waveform signal of a mixed sound;
An output unit for reproducing and outputting the waveform signal output by the mixing unit in synchronization with the synchronization signal output by the sensor;
A control unit;
A power switch;
Have
The control unit outputs a control signal to the pendulum driving unit, and immediately after the power is turned on by the power switch, the pendulum driving unit holds the pendulum driving in a stop state. An electronic metronome that controls the pendulum drive unit to cause the pendulum to reciprocate on the condition that the passage of the pendulum is detected. When the pendulum is reciprocating, the control unit controls to keep the pendulum driving in a stopped state when the sensor does not detect the passage of the pendulum for longer than the tempo period. The electronic metronome according to claim 1, which outputs a signal.

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