JP4707573B2 - Electronic metronome - Google Patents

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 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, the electronic metronome described above has a disadvantage that noise is easily reproduced particularly when the power is turned on or off because the waveform pulses stored in the memory are electrically amplified and reproduced.
An object of the present invention is to provide an electronic metronome capable of eliminating the above-described disadvantages and preventing the occurrence of noise.

In order to achieve the above-described object, an electronic metronome according to a first aspect of the invention includes a pendulum unit that reciprocates at a predetermined tempo, senses the reciprocation of the pendulum unit , and reciprocates the pendulum unit . A sensor that outputs a synchronization signal synchronized with a cycle; a plurality of waveform memories that store at least one beat sound; and at least one tempo sound; and a beat sound and tempo to be selected from the beat sound and the tempo sound. A timbre switching unit that determines and switches sounds, a mixing unit that outputs a waveform signal of a mixed sound by mixing a waveform signal of a beat sound and a waveform signal of a tempo sound stored in the plurality of waveform memories, and the mixing unit D / A conversion circuit for converting the mixed waveform signal into an analog signal and outputting it, and reproducing the waveform signal in synchronization with the synchronization signal output from the sensor, It has an output unit for outputting a control unit, as, under control of the control unit, immediately after the power is turned on, to cut off the output to the output section of the prior SL D / A conversion circuit And a noise removing unit for releasing the interruption of the output to the output unit of the D / A conversion circuit when the sensor senses the reciprocating motion of the pendulum unit for the first time after the power is turned on.

  Preferably, the control unit further includes a clock timer for measuring time, the clock timer measures time from an output of an arbitrary tempo sound, and when the time becomes equal to or longer than a predetermined time, The noise removing unit again shuts off the output of the D / A conversion circuit to the output unit under the control of the control unit.

  ADVANTAGE OF THE INVENTION According to this invention, the electronic metronome which can prevent generation | occurrence | production of noise can be provided.

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, an electronic metronome 100 includes a photosensor 1, a pendulum unit 2, a time signature switching unit 3, a tone color switching unit 4, a power switch unit 5, a control unit 6, waveform memories 71 to 74, a mixing unit 8, A D / A conversion circuit 9, a noise removal unit 10, and an output unit 11 are included.

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 includes, for example, repulsion by a permanent magnet attached to the pendulum unit 2 and rotation of a motor by a battery, 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 11 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.

  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 power switch unit 5 is a switch unit for turning on / off the power source of the electronic metronome 100.
The control unit 6 performs overall control of the electronic metronome 100. In addition, the control unit 6 further includes a timer 61. The timer 61 measures the time from the input of the photosensor 1.

The waveform memories 71 to 74 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, it is assumed that the waveform memory 71 stores the chime sound A, the waveform memory 72 stores the click sound A, the waveform memory 73 stores the chime sound B, and the waveform memory 74 stores the 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 8 mixes the chime sound of the timbre A or the timbre B and the click sound under the control of the control unit 6. That is, the waveform of each sound is read from the waveform memories 71 to 74, 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 6.
The D / A conversion circuit 9 converts the digital waveform signal mixed by the mixing unit 8 into an analog signal.

The noise removing unit 10 removes noise generated when the power source of the electronic metronome 100 is turned on by the power switch unit 5.
The noise removing unit 10 has a circuit configuration as shown in FIG. 3, for example.
As shown in FIG. 3, the noise removing unit 10 includes a capacitor C1, resistors R1 to R3, and a volume. Hereinafter, the power supply potential is described as VDD, and the ground potential is described as GND.
The D / A conversion circuit 9 is AC-coupled to the noise removing unit 10 via the capacitor C1. Further, the node A is input to the output unit 11 via the volume adjustment resistor R3 and volume. Here, an input control transistor TR1 is connected between the capacitor C1 and the resistor R3. The base of the transistor TR1 is connected to the control unit 6 and the power supply potential VDD via a resistor.
Hereinafter, the operation of the noise removing unit 10 when the power source of the electronic metronome 100 is turned on will be described.

  The transistor TR1 is turned on by the pull-up resistor R1 until the control unit 6 starts operating (the control output signal PO1 is output from the control unit 6) after the power source of the electronic metronome 100 is turned on. Therefore, the node A becomes low level, and therefore the analog output AIN from the D / A conversion circuit 9 is cut off from the output unit 11. Further, when the control unit 6 starts operating after the power is turned on, the control output PO1 from the control unit 6 is set to the high level, so that the transistor TR1 remains on, and therefore the node A is also at the low level. Therefore, the analog output AIN remains cut off from the output unit 11. At this time (when the electronic metronome 100 is powered on), the output of the D / A conversion circuit 9 is set to an initial value of 0V.

When there is an initial input to the photosensor 1, the control unit 6 sets the control output signal PO1 to low level and turns off the transistor TR1. Therefore, the analog signal AIN output from the D / A conversion circuit 9 is input to the output unit 11 via the resistor R3 and the volume.
Thereafter, when there is no input to the photosensor 1 for a certain time or longer, for example, longer than the tempo cycle, the control unit 6 sets the control output signal PO1 to high level, turns on the transistor TR1, and shorts the node A to the ground potential GND. The analog output signal AIN is blocked from the output unit 11.
Here, a case where there is no input for a time longer than the tempo period will be described, but the present invention is not limited to this. For example, when there is no input for a time longer than the characteristic threshold time, the control unit 6 sets the control output signal PO1 to high level, turns on the transistor TR1 and shorts the node A to the ground potential GND, thereby outputting the analog output signal. AIN may be blocked from the output unit 11.

  The output unit 11 reproduces and outputs the analog signal AIN input via the noise removing unit 10 as sound.

Next, an operation example of the electronic metronome 100 of this 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 by the power switch unit 5, the control unit 6 sets the control output signal PO1 to high level and outputs it to the noise removing unit 10, and the output of the D / A conversion circuit 9 is output. Set to 0V. In addition, the timer 61 is started.
Step ST2:
The time signature switching unit 3 reads the time signature setting and outputs it to the control unit 6. 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 ST3:
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. When the sensor does not sense the input, the process proceeds to step ST6.
Step ST4:
When there is an input to the sensor in step ST3, the control unit 6 resets the timer 61.

Step ST5:
The control unit 6 sets the control output signal PO1 to a low level and gently changes the output of the D / A conversion circuit 9 to the offset voltage VDD / 2.
Step ST6:
When there is no input to the sensor in step ST3, the control unit 6 causes the timer 61 to continue counting.

Step ST7:
The control unit 6 returns to step ST1 when the count of the time timer 61 becomes equal to or greater than the maximum value of the predetermined time, that is, the tempo period, and returns to step ST3 when it does not exceed the maximum value of the tempo period.
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 unit 2 has swung to “0”. The left / right flag “0” means that the pendulum unit 2 has swung to the right.
Step ST10:
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 ST11:
When the time signature setting of the time signature switching unit 3 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 3 decrements by 1 from the current time signature counter. As a result, the sound for one beat is reproduced.
Step ST13:
When the timbre setting of the timbre switching unit 4 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 6 reads the waveform of the chime sound A from the waveform memory 71 and reads the waveform of the click sound A from the waveform memory 72.
Step ST15:
The mixing unit 8 mixes the waveform of the chime sound A read in step ST14 and the waveform of the click sound A.

Step ST16:
The output unit 11 reproduces and outputs the waveform mixed by the mixing unit 8 in step ST15 as sound.
Step ST17:
The control unit 6 reads the waveform of the chime sound B from the waveform memory 73 and reads the waveform of the click sound B from the waveform memory 74.

Step ST18:
The mixing unit 8 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 8 in step ST18 as a sound.

Step ST20:
If the timbre setting of the timbre switching unit 4 is timbre A, the process proceeds to step ST21, and if it is timbre B, the process proceeds to step ST23.
Step ST21:
The control unit 6 reads the waveform of the click sound A from the waveform memory 72.

Step ST22:
The output unit 11 reproduces and outputs the click sound A read by the control unit 6 in step ST21.
Step ST23:
The control unit 6 reads the waveform of the click sound B from the waveform memory 74.

Step ST24:
The output unit 11 reproduces and outputs the click sound B read by the control unit 6 in step ST23.
Step ST30:
If the time signature setting unit 3 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 6 proceeds to step ST32 when the left / right flag is “1”, that is, when the pendulum unit 2 has just swung to the left, and proceeds to step ST35 when the left / right flag is “0”. move on.
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 6 resets the timer 61.
Step ST34:
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 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 6 resets the timer 61.

Step ST37:
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 ST38:
When the time signature setting of the time signature switching unit 3 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 3 decrements by 1 from the current time signature counter.

Step ST40:
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 ST41. If it is not 0, the process proceeds to step ST49.
Step ST41:
The time signature switching unit 3 newly sets a counter. That is, the counter is returned to “X”.

Step ST42:
If the tone color setting of the tone color switching unit 4 is tone color A, the process proceeds to step ST43, and if it is tone color B, the process proceeds to step ST46.
Step ST43:
The control unit 6 reads the waveform of the chime sound A from the waveform memory 71 and reads the waveform of the click sound A from the waveform memory 72.

Step ST44:
The mixing unit 8 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 8 in step ST44 as sound.

Step ST46:
The control unit 6 reads the waveform of the chime sound B from the waveform memory 73 and reads the waveform of the click sound B from the waveform memory 74.
Step ST47:
The mixing unit 8 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 8 in step ST47 as sound.
Step ST49:
If the tone color setting of the tone color switching unit 4 is tone color A, the process proceeds to step ST50, and if it is tone color B, the process proceeds to step ST52.

Step ST50:
The control unit 6 reads the waveform of the click sound A from the waveform memory 72.
Step ST51:
The output unit 11 reproduces and outputs the click sound A read by the control unit 6 in step ST50.

Step ST52:
The control unit 6 reads the waveform of the click sound B from the waveform memory 74.
Step ST53:
The output unit 11 reproduces and outputs the click sound B read by the control unit 6 in step ST52.

Step ST60:
The controller 6 causes the timer 61 to count.
Step ST61:
The control unit 6 returns to step ST1 when the count of the timer 61 becomes equal to or larger than the maximum value of the tempo period, that is, the maximum value of the tempo period, and returns to step ST30 when it does not exceed the maximum value of the tempo period.

FIG. 7 shows a timing chart when the setting of the time signature switching unit 3 is set to three time signatures as an example of a timing chart of the electronic metronome of the present embodiment.
As shown in FIG. 7, in the operation example of the electronic metronome 100 of the present embodiment, the transistor TR1 of the noise removing unit 10 is turned on after the power is turned on by the power switch unit 5 until the control unit 6 starts to operate. Since it is turned ON, the node A is short-circuited to the ground potential GND. Further, after the operation of the control unit 6 starts, the control unit 6 outputs the control output PO1 at a high level until the photosensor 1 senses an input, so that the transistor TR1 remains ON, and the node A is shorted to the ground potential GND. It has been done. When the power is turned on, the control unit 6 sets the output of the D / A conversion circuit 9 to an initial value of 0 V. That is, in the electronic metronome 100 of this embodiment, before the control unit 6 starts operating when the power is turned on. Generation of noise due to the output signal of the transient D / A conversion circuit 9 can be prevented.

  Furthermore, as shown in FIG. 7, in the operation example of the electronic metronome 100 of the present embodiment, when the photosensor 1 is initially input, the control unit 6 sets the control output signal PO1 to the low level and turns the transistor TR1 on. Since the output voltage of the D / A converter circuit is gently changed from the initial value of 0 V to the offset voltage VDD / 2, the waveform signal of the beat sound or the tempo sound is converted into the waveform memory 71 to responsive to the sensor input. The data can be read from 74 and reproduced / output by the output unit 11.

  Furthermore, as shown in FIG. 7, in the operation example of the electronic metronome 100 according to the present embodiment, the control unit 6 counts the time with the clock timer 61, and there is no sensor input for a time exceeding the maximum value of the tempo cycle. The control unit 6 sets the control output signal PO1 to the high level to turn on the transistor TR1 of the noise removing unit 10 to short-circuit the node A with the ground potential GND, thereby gradually changing the D / A conversion output from the offset voltage VDD / 2 to 0V. Therefore, even if the power source of the electronic metronome 100 is turned off by the power switch unit 5 at this time, the generation of noise due to the output signal of the transient D / A conversion circuit can be suppressed.

  As described above, according to the electronic metronome 100 of the present embodiment, the transistor TR1 of the noise removing unit 10 is turned on until the control unit 6 starts operating after the power is turned on by the power switch unit 5. Therefore, since the node A is short-circuited to the ground potential GND, and after the operation of the control unit 6 is started, the control unit 6 outputs the control output PO1 at a high level until the photosensor 1 senses the input, so that the transistor TR1 is turned on. The node A remains shorted to the ground potential GND, and the control unit 6 sets the output of the D / A conversion circuit 9 to the initial value of 0 V when the power is turned on, so that the control unit 6 operates when the power is turned on. It is possible to prevent the generation of noise due to the output signal of the transient D / A conversion circuit 9 before starting the operation.

  Further, according to the electronic metronome 100 of this embodiment, when the photosensor 1 is initially input, the control unit 6 sets the control output signal PO1 to the low level to turn off the transistor TR1 and performs D / A conversion. The output voltage of the circuit is gently changed from the initial value of 0 V to the offset voltage VDD / 2, and the waveform signals of the beat sound and the tempo sound are read from the waveform memories 71 to 74 in accordance with the sensor input and reproduced / output to the output unit 11. Can be output.

  Further, according to the electronic metronome 100 of the present embodiment, the control unit 6 causes the timekeeping timer 61 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 unit 6 controls the control output signal PO1. Is set to the high level to turn on the transistor TR1 of the noise removing unit 10 and short-circuit the node A with the ground potential GND, thereby gradually changing the D / A conversion output from the offset voltage VDD / 2 to 0V. Even when the power switch 5 is turned off, noise can be prevented.

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.

  In the electronic metronome 100 of the present embodiment, the noise removing unit 10 has a circuit configuration as shown in FIG. 3, but this is an example, and the present invention is not limited to this. The present invention can also be realized by the noise removing unit 10 having another equivalent circuit configuration.

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 71, a waveform of a click sound is stored in advance in the waveform memory 72, and the waveform memories 73 and 74 may allow the user to store a waveform of a free tone. 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 illustrating a configuration example of the noise removing unit 10. 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.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 100 ... Electronic metronome, 1 ... Photo sensor, 2 ... Pendulum part, 21 ... Adjusting weight, 22 ... Reflector plate, 3 ... Time signature switching part, 4 ... Tone switching part, 5 ... Power switch part, 6 ... Control part, 61 ... Timekeeping timer, 71, 72, 73, 74 ... Waveform memory, 8 ... Mixing unit, 9 ... D / A conversion circuit, 10 ... Noise removing unit, 11 ... Output unit, AIN ... Analog signal, PO1 ... Control output signal , R1, R2, R3 ... resistance

Claims (2)

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 at least one time signature and at least one tempo;
A tone color switching unit that determines and switches a time signature sound and a tempo sound to be selected from the time signature sound and the tempo sound;
A mixing unit for mixing a waveform signal of a beat sound and a waveform signal of a tempo sound stored in the plurality of waveform memories to output a waveform signal of a mixed sound;
A D / A conversion circuit for converting the waveform signal mixed by the mixing unit into an analog signal and outputting the analog signal;
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;
Have
Under the control of the control unit, immediately after the power is turned on, prior SL is cut off the output to the output section of the D / A conversion circuit, the power supply from the turned on the sensor of the pendulum portion An electronic metronome further comprising: a noise removing unit that releases an interruption of an output to the output unit of the D / A conversion circuit when a reciprocating motion is sensed for the first time . The control unit further includes a timer for measuring time,
The time measuring timer measures the time from the output of an arbitrary tempo sound, and when the time exceeds a predetermined time, the noise removing unit controls the D / A conversion circuit under the control of the control unit. The electronic metronome according to claim 1 , wherein the output to the output unit is shut off again .

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